DE102023100464A1 - Method for operating a direct current electric furnace for producing molten iron and liquid slag - Google Patents

Abstract

The invention relates to a method for operating a direct current electric furnace (10) with at least one upper electrode (11) and at least one lower electrode (11.1) for producing an iron melt (1) and a liquid slag (2).

Description

The invention relates to a method for operating a direct current electric furnace for producing molten iron and liquid slag.

Liquid iron production via fossil-based blast furnace routes generates a lot of CO ₂ .

Natural gas-powered direct reduction (plants) emit significantly less CO ₂ , but the result is solid sponge iron. The direct reduction route also offers the possibility of working with high hydrogen content in the process gas, which can potentially reduce overall CO ₂ emissions. It does not matter which direct reduction process is used, be it vertical shafts or rotary kilns, as long as the product is solid sponge iron. High production outputs mean that such plants are more likely to be operated at an economic optimum, so that a complete reduction of the sponge iron does not necessarily have to occur.

The solid sponge iron must be melted in melting units, whereby different approaches can be used, such as induction furnaces or electric arc furnaces or even melt reduction furnaces. In the melting process, the sponge iron is melted and the already reduced portion in the sponge iron separates into a metallic phase (molten iron) from the non-reduced portion. The non-reduced portion is then discharged into the liquid slag in the usual melting process, which results in a suboptimal yield and an increased amount of liquid slag with higher iron contents.

This disadvantage does not occur in manufacturing processes with a combined direct reduction process with a smelting reduction furnace, but this smelting process is absolutely dependent on a reducing agent in the form of carbon in the smelting furnace. The iron melt produced in this way ("electric pig iron") must then be further processed in at least one subsequent refining step, e.g. to make steel melt. In order to be CO ₂ -neutral or reduced, the carbon added must at least be fossil-free and, ideally, the CO ₂ produced during the process never leaves the process (carbon looping).

The use of direct current electric furnaces for the production of iron melts and liquid slags from charged solids containing iron and slag formers is state of the art, see for example EP 0 657 549 B1 , EP 1 124 995 B1 , DE 197 44 151 C5 .

The object of the present invention is to provide a method for operating an electric melter with which an optimal yield and a reduced amount of liquid slag with a lower iron content up to essentially complete removal of the iron content can be achieved compared to the prior art.

This object is achieved by a method having the features of claim 1. Further embodiments are described in the subclaims.

The invention relates to a method for operating a direct current electric furnace with at least one upper electrode and at least one lower electrode for producing an iron melt and a liquid slag, comprising the steps of: - charging the melter with solids containing iron-containing material and slag formers; - melting the solids to produce an iron melt and a liquid slag arranged on the iron melt, wherein during the melting of the solids the upper electrode functions as a cathode and the lower electrode as an anode; - tapping the liquid slag and the iron melt; wherein before the liquid slag and the iron melt are tapping, the upper electrode is brought into contact with the liquid slag and a polarity reversal is carried out and thus the upper electrode functions as an anode and the lower electrode as a cathode.

In the simplest design, the direct current electric furnace has an upper electrode and a lower electrode. Depending on the geometry and design of the electric furnace, however, two or three upper electrodes and/or two or three lower electrodes can also be provided. In the following, we will refer to upper electrode and lower electrode, but these can be understood as a plural. The working principle/operation of direct current electric furnaces is familiar to the person skilled in the art, so that after charging the melter with solids containing iron-containing material and slag formers, the step of melting the solids is initiated to produce an iron melt and a liquid slag arranged on the iron melt, whereby the upper electrode functions as a cathode and the lower electrode as an anode during the melting of the solids. This allows a stable and in particular straight plasma arc to strike the solids to be melted from the cathode. In other words, the direct current electric furnace is preferably operated as an arc furnace, whereby the upper electrode is spaced apart from the lower electrode. to the solids to be melted. Alternatively, the upper electrode can also be positioned in contact with the solids to be melted, whereby the solids are then heated by means of the Joule effect. Both functional principles are familiar to the expert.

Once the solids have largely melted, the upper electrode is brought into contact with the liquid slag and the molten iron before the tapping off of the liquid slag and the polarity is reversed so that the upper electrode acts as an anode and the lower electrode as a cathode.

By bringing the upper electrode into contact with the liquid slag and reversing the polarity, the oxygen still bound in the non-reduced portions of the iron-containing materials that were transferred into the liquid slag during melting can be separated, so that additional liquid iron can enter the iron melt through the reaction Fe ₂ O ₃ + e- → 2 Fe + 3/2 O ₂ and thus less liquid slag, in particular with little to essentially no iron content, can be provided and thus tapped. Essentially, the iron oxide is electrochemically deoxidized by applying an electrical voltage according to the electrochemical voltage series known to those skilled in the art.

Contact with the liquid slag is not only to be understood superficially by placing the upper electrode on the liquid slag surface, but can also be understood as immersion in the liquid slag. However, contact with the molten iron located below the liquid slag must be avoided in order to prevent a direct short circuit between the anode and cathode. A short circuit due to direct contact with the molten iron would lead to a significant deterioration in efficiency, so the immersion depth is limited to less than the thickness of the liquid slag.

The invention makes use of the fact that in this configuration, prior to tapping, a fused salt electrolysis takes place due to the polarity reversal. The principle of fused salt electrolysis is exemplified in the EP 2 609 231 B1 described, whereby the teaching in this publication takes place in comparison to the invention of other parameters, namely a carbon dioxide-free production of liquid metal by using natural (non-reduced) ores. This temporary procedure has the advantage over the conventional methods for producing an iron melt and liquid slag that the yield of the iron melt is higher, especially with a comparable or even reduced energy requirement. In addition, the melting of pre-reduced iron does not have the disadvantage that the overall production output of iron is significantly higher than when exclusively produced via the molten salt electrolysis mentioned as an example from the EP 2 609 231 B1 , since only the non-reduced portion of iron oxides in the liquid slag is reduced. This also has the advantage, compared to the example of fused salt electrolysis, that significantly shorter process times can be achieved.

According to one embodiment, the iron-containing material contains or consists of sponge iron. The sponge iron originating from a direct reduction process does not necessarily have to be completely reduced, so that the degree of metallization of the sponge iron used can be between 20 and 95%. The degree of metallization can in particular be at most 90%, preferably at most 80%, preferably at most 70%. The determination of the degree of metallization is known to the person skilled in the art, in particular it can be determined by (Fe _elemental / Fe _total ) * 100 in the sponge iron.

According to one embodiment, a carbon-containing additive can also be charged. The additional carbon-containing additive contributes to increasing the carbon content in the molten iron. By charging the carbon-containing additive, an enrichment of the carbon content in the molten iron to at least 2.50 wt. %, in particular to at least 3.00 wt. %, preferably to at least 3.50 wt. %, more preferably to at least 4.00 wt. Setting a value of more than 5.5 wt. % carbon in the molten iron is not technically sensible. The additional carbon-containing additive can be charged in solid, gaseous and/or liquid form. This can be done via a solid form such as biocoke, coke, coal; via a gaseous form as carbon-containing or hydrocarbon-containing gases, including metallurgical gases, in particular coke oven gas, converter gas, blast furnace gas from electric smelters; via a liquid form such as alcohol, hydrocarbon, biofuel.

In order to improve or increase the recycling rate, according to one embodiment, additional scrap can be charged. This can be done, for example, in such a way that > 0 kg, in particular at least 20 kg, preferably at least 50 kg, preferably at least 80 kg up to 200 kg of scrap can be charged per ton of molten iron produced.

According to one embodiment, the charging of the slag formers can be such that a basicity B3 in the liquid slag of between 0.9 and 1.8 is established. B3 can in particular be at least 1.0, preferably at least 1.1 and in particular a maximum of 1.7, preferably a maximum of 1.6. The basicity B3 corresponds to the ratio (CaO+Mg ₂ O) to (SiO ₂ +Al ₂ O ₃ ), whereby the determination of the characteristic sizes in the slag in the solid state is familiar to the person skilled in the art. The slag former comprises at least one or more of the elements from the group (CaO, Mg ₂ O, SiO ₂ , Al ₂ O ₃ ). In a preferred use of sponge iron, which is obtained from iron ore consisting of oxidic iron (iron oxide) and gangue, whereby the proportions can differ depending on the mining site, by means of direct reduction to metallic iron and gangue. If the gangue is not sufficient, B3 slag formers are added to adjust the basicity to be achieved.

According to one embodiment, the energy required for melting is provided from renewable energy (sun, wind, water, biomass). This allows the direct current electric furnace to be operated in a more climate-neutral manner.

The direct current electric furnace can preferably be a furnace of the open slag bath furnace type. These include electric submerged arc furnaces, especially direct current submerged arc furnaces (submerged arc furnaces dc), which work with arc resistance heating by generating arcs between the electrode and the solids and/or the liquid slag or by heating the solids and/or the slag using the Joule effect. Alternatively, melting furnaces with direct arc action can also be used, especially direct current electric arc furnaces (dc) or direct current ladle furnaces (dc).

• In den 1 und 2 wird die Erfindung am Beispiel eines Gleichstrom-Elektroofens (10) mit mindestens einer Oberelektrode (11) und mindestens einer Unterelektrode (11.1) in einer schematischen Seitenaufsicht erläutert. Der Gleichstrom-Elektroofen (10) umfasst ein Gefäß (15) und mindestens eine Unterelektrode (11.1), welche bevorzugt als Bodenelektrode im Boden des Gefäßes (15) angeordnet ist. Der Gleichstrom-Elektroofen (10) kann einen Deckel (16) umfassen, welcher das Gefäß (15) nach oben verschließen kann und somit innerhalb des Gleichstrom-Elektroofens (10) eine definierte bzw. gezielte, vorzugsweise reduzierende Atmosphäre eingestellt werden kann. Der Deckel (16) kann im Wesentlichen vertikal verfahrbar angeordnet sein, s. Doppelpfeil. Ist ein Deckel (16) vorhanden, so sind Chargierstellen (12) in Form von Öffnungen in dem Deckel (16) mit entsprechenden Zufuhrleitungen vorgesehen, durch welche der Gleichstrom-Elektroofen (10) chargiert wird. Chargiert wird der Gleichstrom-Elektroofen (10) mit Feststoffen (17) enthaltend eisenhaltiges Material und Schlackenbildner.

The invention is explained in more detail using the following embodiments in conjunction with the drawing.

• In the 1 and 2 the invention is explained using the example of a direct current electric furnace (10) with at least one upper electrode (11) and at least one lower electrode (11.1) in a schematic side view. The direct current electric furnace (10) comprises a vessel (15) and at least one lower electrode (11.1), which is preferably arranged as a bottom electrode in the bottom of the vessel (15). The direct current electric furnace (10) can comprise a lid (16) which can close the vessel (15) at the top and thus a defined or targeted, preferably reducing atmosphere can be set within the direct current electric furnace (10). The lid (16) can be arranged so as to be movable essentially vertically, see double arrow. If a lid (16) is present, charging points (12) in the form of openings in the lid (16) with corresponding supply lines are provided through which the direct current electric furnace (10) is charged. The direct current electric furnace (10) is charged with solids (17) containing iron-containing material and slag formers.

The iron-containing material contains or consists of sponge iron, whereby the degree of metallization of the sponge iron can be between 50 and 95%. In addition, scrap can also be charged as another iron-containing material, for example with > 0 kg up to 200 kg of scrap per tonne of molten iron produced (1). The slag former comprises at least one or more of the elements from the group (CaO, Mg ₂ O, SiO ₂ , Al ₂ O ₃ ) and can be dimensioned such that a basicity B3 in the liquid slag (2) of between 0.9 and 1.8 is established. If required, a carbon-containing additive can also be charged such that the carbon content in the molten iron (1) is enriched to at least 2.50 wt.%.

If the direct current electric furnace (10) is sufficiently charged with solids (17), the operation of the direct current electric furnace (10) can begin and the at least one upper electrode (11) is positioned above the solids (17). An arc is ignited between the solids (17) and the upper electrode (11) so that the solids (17) are gradually melted to produce an iron melt (1) and a liquid slag (2) arranged on the iron melt (2), wherein the upper electrode (11) functions as a cathode (-) and the lower electrode (11.1) as an anode (+) while the solids are melting. The direct current electric furnace (10) can be successively charged further with solids (17) until the desired output of the iron melt (1) is achieved. The energy required for melting is preferably provided from renewable energy. When all solids (17) have largely melted, the liquid slag (2) still contains non-reduced portions of the iron-containing materials.

At the same time or at different times, the upper electrode (11) is brought into contact with the liquid slag (2) and the polarity is reversed so that the upper electrode (11) acts as an anode (+) and the lower electrode (11.1) as a cathode (-). If there are several upper electrodes, not shown here, it is also possible to polarize them alternately as anode and cathode. Then the polarity is reversed, preferably by immersion, see double arrow, the upper electrode (11) into the liquid slag (2) without dipping into the iron melt (1). In addition to the improved iron yield from the liquid slag (2), liquid electrolysis can also contribute to slag conditioning, among other things until the desired basicity B3 is achieved. If the specifications for the iron melt (1) and liquid slag (2) in particular are met, the iron melt (1) produced in the vessel (15) and the liquid slag (2) arranged on the iron melt (1) are ready for tapping.

The liquid slag (2) is tapped off via, for example, a tapping point (13) and the molten iron (1) is tapped off via a tapping point (14) in the vessel (15).

Not shown, nozzles can be arranged in the vessel (15), in particular in the bottom of the vessel (15), to influence the movement of the molten iron (1). The direct current electric furnace (10) can also be pivotally mounted to allow tilting and thus tapping of liquid slag (2) in one direction and molten iron (1) in the other direction.

Also not shown is how the iron melt (1) is removed and fed to a further processing step. The iron melt (1) is preferably fed to a treatment in order to reduce the carbon in the iron melt (1) to a desired level. This is done, for example, using oxygen in a so-called oxygen blowing process, particularly preferably in a converter. The tapped liquid melt (2) is also preferably fed to a granulation process in order to produce slag, in particular for the construction industry.

Also not shown is how the gases produced in the lid are removed and treated. Preferably, the gases and dust can be extracted separately from the melting phase and the electrolysis phase, respectively, since the resulting exhaust gas contains oxygen.

The electrodes (upper and lower electrodes) are made of suitable materials such as WC, Ti-Ir, Pt, C, graphite or mixtures thereof. The mixtures can also be used as an additive to Söderberg electrodes. Coated electrodes can also be used, such as ceramic rods that have been coated or doped with the aforementioned material.

The electrical voltage is preferably 3V, in order to generate an overpotential. A higher voltage increases the yield, but in return causes greater wear on the electrodes and a reduction in accompanying elements.

QUOTES INCLUDED IN THE DESCRIPTION

This list of documents listed by the applicant was generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA accepts no liability for any errors or omissions.

Cited patent literature

• EP 0657549 B1 [0006]
• EP1124995B1 [0006]
• DE 19744151 C5 [0006]
• EP 2609231 B1 [0014]

Claims (6)

Method for operating a direct current electric furnace (10) with at least one upper electrode (11) and at least one lower electrode (11.1) for producing an iron melt (1) and a liquid slag (2), comprising the steps of: - charging the electric furnace (10) with solids containing iron-containing material and slag formers; - melting the solids to produce an iron melt (1) and a liquid slag (2) arranged on the iron melt (1), wherein during the melting of the solids the upper electrode (11) functions as a cathode and the lower electrode (11.1) functions as an anode; - tapping the liquid slag (2) and the iron melt (1); characterized in that before tapping the liquid slag (2) and the iron melt (1), the upper electrode (11) is brought into contact with the liquid slag (2) and a polarity reversal is carried out and thus the upper electrode (11) functions as an anode and the lower electrode (11.1) as a cathode. Procedure according to Claim 1 , wherein the ferrous material contains or consists of sponge iron, the degree of metallisation of the sponge iron being between 20 and 95 %. Method according to one of the preceding claims, wherein a carbon-containing additive is additionally charged. Method according to one of the preceding claims, wherein scrap is additionally charged. Process according to one of the preceding claims, wherein the charging of the slag formers is such that a basicity B3 in the liquid slag of between 0.9 and 1.8 is established. Method according to one of the preceding claims, wherein the energy required for melting is provided from renewable energy.