EP1753884A1 - Agglomerated stone for using in shaft furnaces, corex furnaces or blast furnaces, method for producing agglomerated stones, and use of fine and superfine iron ore dust - Google Patents

Abstract

Agglomerated stone comprising (wt.%):cement binding agent (6-15), carbon carrier (up to 20), residual and recyclable substances (up to 20), and optionally accelerator (up to 10), remainder iron ore stone in the form of particles of grain size below 3 mm. After 3 days the iron ore has an initial strength of at least 5 N/mm2> and after 28 days a cold compression strength of at least 20 N/mm2>. An independent claim is included for a method of preparing the stone as described above by transfer of the composition to a mold and compacting.

Description

 AGGLOMERATEINSTEIN FOR USE IN SHAFT, COREX OR BLAST MILLS, METHOD FOR THE PRODUCTION OF AGGLOMERATSTEINEN AND USE OF IRON ORE FINE AND FINE DUST

The invention relates to an agglomerate stone for use in shaft, Corex or blast furnaces, a method for producing such agglomerate stones and the use of fine or very fine iron ore dusts.

In the extraction, processing, preparation and processing of ores, iron-containing dusts with the finest and fine grain of up to 3 mm are obtained in large quantities. In order to be able to use these dusts for metal production, they have to be cut into pieces. Sintering and pelleting are common processes for making fine and fine ores used in smelting.

When sintering ore dust, a mixture of moistened fine ore together with coke breeze or another carbon carrier and aggregates of limestone, quicklime, olivine or dolomite is usually placed on a circumferential grate, the so-called "sintering belt" and ignited from above. The carbon contained in this mixture burns with the help of the air drawn through the sintering belt, causing the ore grains to cake. When the end of the sintering belt is reached in this way the layer on the belt is completely sintered. The solidified iron ore is broken, sieved while still glowing and fed to a cooler, in which it is cooled so gently that its strength is not impaired. The sinter obtained after further screening of the fine components of the cooled sinter mixture is suitable for direct use in the blast furnace due to its high gas permeability and good reducibility.

The known sintering process can usually only economically bring ore dusts into a lumpy form that have grain sizes of 2 mm and more. Ore dust with a significantly lower grain size can be used for metal extraction by pelleting.

When pelleting, fine ores and concentrates with grain sizes well below 1 mm are formed into small balls, the diameter of which is 10 - 15 mm in the usual procedure. For this purpose, the ore dust is moistened and mixed with up to 10% by weight of a binder consisting, for example, of blast furnace slag and cement. This mixture then turns into "green pellets" in rotary drums or on turntables. The green pellets that are still moist are dried and fired at temperatures above 1000 ° C in a shaft furnace, rotary kiln or on a traveling grate. A detailed description of the prior art in the field of pelleting of finely grained dusts containing metal oxide can be found in DE 33 07 175 AI.

The pellets produced by pelleting can have a uniform grain compared to lump ores, a constant one Quality and good gas flow during the reduction can be guaranteed. However, there is a risk that the pellets will cake together during their reduction or lose their shape, with the result that the reduction cannot be carried out with the desired success. In addition to the complex and costly way of producing them, pellets can therefore only be used to a limited extent.

Another method of using iron oxide present in fine-grained form for the production of raw rice is described in the method by Michael Peters et al. written lecture "Oxygen Cupola for recycling waste oxides from at integrated steel plant", on 17 June 2003 at the 3 ^rd International Conference on Science and Technology of Steelmaking METEC Congress 03 in Dusseldorf, Germany, presented and in the article "A new process for recycling steelplant wastes "by Christian Bartels-von Varnbueler, which can be found on the Internet at the URL" http://briket.ru/eng/related_articles.shmtl ". With this known process, which is also known under the name "OxiCup process", it is possible to use large amounts of iron oxide residues, which are accumulated as residual or recycle substances in the form of filter dusts in pig iron production, as recycling -Material attributed to the melting process. For this purpose, the residues (iron oxide dusts) of the iron production present in fine to very fine-grained form are mixed with a carbon carrier, such as coke breeze, with water and with a cement which acts as a binder. Blocks are formed from the mixture, which have a hexagonal base. After drying, the blocks thus obtained are on the one hand so easy to pour and flow that they can be placed in the OxiCup furnace used for iron production without any problems. On the other hand, they are so stable and strong that they can also withstand the loads that arise in the furnace due to the material column moving on them.

The blocks are then heated to a temperature above 1000 ° C when they sink from the high filling position towards the hot zone of the OxiCup furnace. The carbon carrier contained in the blocks is converted into CO gas, which causes a direct reduction in the iron oxide content of the blocks. The OxiCup process thus provides an economical method for reusing dusts from iron production.

When extracting and processing iron ore, large amounts of fine ore and fine dust in the form of stone are produced in the area of the deposit. The storage and disposal of these dusts represents a considerable problem, since the high costs associated with the sintering or pelleting of these dusts make economic use more difficult. This leads to considerable problems in the disposal of the fine or fine dust at the site of ore extraction or processing.

In order to be able to use the ore dust that was not previously usable in an economical manner, the invention proposes an agglomerate stone for use in shaft, Corex or blast furnaces, which (in% by weight) 6 - 15% of a cement binder, up to 20% of a carbon carrier, up to 20% of residual and recyclable materials, optionally up to 10% of a solidification and solidification accelerator, and the remainder of the iron ore present in stone format in the form of particles with a grain size of less than 3 mm and an early strength of at least after three days 5 N / mm ² and after 28 days has a cold compressive strength of at least 20 N / mm ² .

In contrast to the state of the art, iron ore fine and very fine dusts which are in stone format are used in accordance with the invention. Such iron ores contain essentially no metallic iron, but only pure iron oxide, which can be contaminated with little gait. Therefore, agglomerate stones according to the invention have fundamentally different properties than those in. State of the art so far from residual and circular waste stones.

Ore stones of the type according to the invention have a significantly higher early and final strength than the known residual material stones. Due to the high compressive strength of at least 20 N / mm ² present in the finished state in the case of agglomerate stones according to the invention, they can safely withstand the pressure of the pouring column in the blast furnace.

At the same time, agglomerate stones according to the invention regularly achieve a minimum hot compressive strength of 10 N / mm ² .

The composition of the ore stones according to the invention is coordinated with one another in such a way that in blast furnace use, when the binding properties of the cement material collapse with increasing temperature and heating duration, the latter Temperature-forming sponge iron as a supporting structure, the gas permeability of the stone and of the entire furnace content can be maintained. The particular strength and shape retention of agglomerate stones according to the invention make these stones particularly suitable for use in shaft, Corex or blast furnaces.

With the agglomerate stones according to the invention, it is thus possible to utilize fine and very fine dusts which are inexpensively obtainable and which have not hitherto been usable and which arise in the extraction and processing of iron ores at the deposit itself, for iron production. Due to the use of cements as binders, even the finest dusts can be formed into a solid block, which has optimal usage properties both for its manufacture and for its use.

As a further positive effect of the invention, in addition to the economic advantages achieved by the invention, there is a significant reduction in the environmental impact in the area of the extraction and processing sites for ore extraction. Ore dusts that have so far been released into the environment and have caused considerable damage there, particularly in the waters, can be used profitably with the invention.

The fact that agglomerate stones according to the invention can contain up to 20% of residual and circular substances also contributes to the advantages of the invention with regard to the problem of disposal of residual and circular substances. These substances are mixtures of materials which, in addition to iron in metallic and oxidic form Contain impurities. Such residual and recycle materials occur, for example, in the production and processing of steel in the form of filter dusts, top dusts or mill scale.

The final strength of the agglomerate stones according to the invention is in each case so high that they withstand the loads which occur when used in the respective furnace. Since agglomerate stones according to the invention can be significantly larger, they are suitable for use in large furnaces, such as shaft, Corex or blast furnaces, and there ensure the improved gasification during the reduction.

At the same time, the early strength of the agglomerate stones obtained according to the invention is sufficient for them to be able to be transported a short time after their manufacture. This makes it possible, for example, to stack the agglomerate stones according to the invention soon after they have been formed in a drying room, in which they can then be dried particularly effectively.

Agglomerate stones according to the invention can be produced on stone-making machines known per se, such as are used for example for the production of paving stones. Such block making machines allow a particularly cost-effective production and contribute to the fact that agglomerated stones according to the invention can be produced at a particularly favorable ^• the economics of their use further enhancing price.

Complex heat treatments, such as those required for sintering or pelleting, are for the Production of the stones according to the invention is not necessary. For example, the roasting gases that are unavoidable during sintering are saved and the environment is significantly relieved.

Practical tests have shown that agglomerate stones according to the invention enable the economical use of iron ore dusts over the entire width of the conceivable grain sizes up to 3 mm. This means that dusts with a grain size of up to 1 mm can be processed and used just as easily as iron ore dust with a grain size of up to 500 μm that typically occurs in the area of certain deposits. Such ore dust, which is obtained in the range from 5 to 30 μm when pelleting iron ores, so-called "pellet feed", can also be used in that agglomerate stones according to the invention are produced from them. Studies also show that even dusts collected in aqueous solution and produced in the production of ore concentrates with grain sizes of up to 7 μm can be used profitably for iron production if they are used to form agglomerate stones according to the invention.

The iron ores contained in fine-grained agglomerate stones according to the invention are preferably in haematitic (Fe ₂ 0 ₃ ), magnetitic (Fe ₃ 0 ₄ ) and / or wustitic (FeO) modification, the grain diameter of which is also preferably less than 0.1 mm.

It should be emphasized here in particular that the invention also makes it difficult to sinter or pelletize to supply ferrous materials for the production of pig iron. Accordingly, iron ore in the form of geothite (FeO (OH)) can be used for the production of agglomerate stones according to the invention. This applies even if the geothite has a grain size of up to 2 mm, whereby grain sizes that are significantly smaller than 2 mm can also be used.

In order to use it as effectively as possible

To ensure pig iron extraction, the content of iron should be at least 40% by weight in an agglomerate stone according to the invention.

The invention makes use of the idea, already known per se, of coldly binding the iron dust to be used in stone form without special heat treatment with the aid of a cement. In addition to the use of iron dusts that are difficult to sinter or pelletize, as mentioned above, cement binding also enables slag guidance, in particular its proportions of MgO, CaO, SiO ₂ , Al ₂ O ₃ , during the production of pig iron, via the respective cement portion of the agglomerate stone. to vary.

Portland cement or metallurgical cement, which is available at low cost, can be used as the cement binder. The binder in question is mixed with the iron ore dust as a hydraulic cement phase. Particularly good usage properties with at the same time optimized resource conservation arise when agglomerate stones according to the invention contain 6 to 15% by weight of cement binder. With cement contents measured in this way, the early strength determined after 3 days becomes at least 5 N / mm ² and that which can be determined after 28 days Cold compressive strength of at least 20 N / mm ^{2 achieved} in each case particularly reliably with agglomerate stones according to the invention. Depending on the content of its other constituents, however, it may also make sense to increase the cement binder content by up to 20% by weight or to reduce it to less than 5% by weight.

The special behavior of the agglomerate stones according to the invention when heated has turned out to be particularly advantageous for use in a furnace for producing pig iron. The embedding of the iron ore dust present in stone format in a cement binder at temperatures of up to 400 ° C. results in an increase in strength. In the temperature range of more than 400 ° C to 800 ° C there is only a slow decrease in strength. Due to this behavior, the agglomerate stones keep their shape as long as they pass through the furnace, so that they are safely transported to the hot melting zone. Only at temperatures above 800 ° C to 1000 ° C does their strength drop faster. The iron sponge formed in this temperature range during the reduction ensures the shape retention of the agglomerate stone during further heating and maintains its gas permeability.

If this is useful from a production point of view, for example for maintaining certain cycle times, the agglomerate stone according to the invention can, in addition to the cement binder, optionally also a setting and solidification accelerator, such as water glass, alumina cement, calcium chloride, an alkali salt, in particular a Na salt, or a Cellulose glue, such as paste, included. The ore stones processed according to the invention in dust form can be used both directly-reducing with a reducing agent (carbon carrier) and without a reducing agent. If a reducing agent is present, the maximum content of the carbon carrier in the agglomerate stone should not be more than 20% by weight. In this case, an optimal adaptation of the proportion to the proportion by weight of iron is achieved if the agglomerate stone contains 8-15% by weight of the carbon carrier. However, if the proportion of volatile components in an agglomerate stone according to the invention is high, the otherwise reduced reducibility can be compensated for by increased contents of the C-carrier component.

In principle, all materials with reducible free carbon are suitable as carbon carriers. So coke dust, coke quenching, coke breeze or anthracite coal come into question. The grain size of the carbon carrier is preferably up to 2 mm. C-beams with such a grain size are available at particularly low cost and are difficult to use when extracting iron.

Agglomerate stones according to the invention should have a cylindrical, cuboid or polygonal shape, on the one hand to ensure sufficient stability and on the other hand after filling into the furnace to ensure that there are sufficient gaps between them for the through-gasing of the bed. In particular when the agglomerate stones have a block shape with a polygonal, in particular hexagonal, base area, the shaping surface is optimally used. As a "green body", ie after it has been shaped while still moist, the water content of the agglomerate stone according to the invention should be less than 25%. The production of earth-moist, crumbly green bodies is simplified compared to the processing of masses with a higher moisture content. In addition, by limiting the water content of the green bodies according to the invention, it is avoided that excess water in the oven has to be expelled with high energy expenditure.

Surprisingly, it has been shown that agglomerate stones according to the invention, when reduced during a standardized RuL test ("RuL" = Reduction under Load), achieve a degree of reduction of at least 80%, in particular up to 100% (degree of reduction [%] = (Fe _me t / Fe _tot ) 100%).

By the invention proposing the use of fine and fine ore in stone format with a grain size of up to 3 mm for the production of agglomerate stones, such ore stone dust can also be used for the production of pig iron which up to now could only be used with difficulty or not economically for this purpose ,

Agglomerate stones according to the invention are particularly easy to produce. For this purpose, stone-like iron ore in the form of fine or very fine dust with a maximum grain size of 3 mm with a binder present as a hydraulic cement phase as well as optionally with a carbon carrier, with residual and circulating materials and / or a solidification and solidification accelerator with the stipulations mixed that the proportion of cement binder in the mixture obtained (in wt .-%) 6 - 15%, the proportion of the carbon carrier up to 20%, the proportion of residual and circulating materials up to 20% and the proportion of solidification and solidification accelerators up to 10%. The mixture obtained is filled into molds. According to a first process variant, the mixture is then pressed before it is dried. Alternatively, however, it is also possible, instead of pressing, to shake the mixture filled into the mold in order to achieve the most homogeneous possible distribution and connection of the individual components of the mixture. Optimal properties of the agglomerate stones can be achieved if the pressing and shaking are carried out in combination or in a suitable manner in succession.

The invention is explained in more detail below on the basis of exemplary embodiments. Show it:

Diag. 1 the strength of an agglomerate stone according to the invention plotted against the temperature;

Diag. 2 the strength of a conventional agglomerate stone plotted against temperature;

Diag. 3a the temperature of an agglomerate stone according to the invention plotted over the heating time,

Diag. 3b the stone height of an agglomerate stone according to the invention plotted over the heating-up time,

Diag. 3c shows the weight loss of an agglomerate stone according to the invention plotted over the heating-up time. In the experiments described below, the agglomerate stones examined were each subjected to the so-called "modified RuL test". In this test, the melting behavior of the agglomerate stones in the chimney shaft is simulated with a chimney gas atmosphere under static conditions. In this way, statements can be made as to whether the formation of sponge iron from the reduction of the iron carriers of the agglomerate stones is sufficient to counteract the breakdown of the cement bond that occurs with increasing warming, without the gasification of the chimney being negatively affected by softening or disintegration of the agglomerate stones is hindered. The simulation ends in the temperature range of 1000 - 1100 ° C.

Experiment I

In the first experiment, the reduction behavior of agglomerate stones from fine to fine-grained haematitic iron ore dust, which was generated as a pellet feed during pellet production, was investigated. The grain size of the iron ore dust was between 5 and 30 μm.

The iron ore dust was mixed with coke in the form of coke dust as a carbon carrier and a quick-setting, commercially available standard cement as a cement binder. The mixture obtained contained (in% by weight) 70 to 80% iron dust, 10 to 15% coke and 10 to 15% cement binder. The mixture composed in this way was shaken in a known stone molding machine and pressed to block-shaped agglomerate stones, which had a hexagonal base with an edge length of approx. 30 mm and a height of 110 mm. After drying, the agglomerate stones were subjected to the RuL test. This resulted in a degree of reduction

("Metallization") of the fine - grained haematite ore dust of 95.2% and a decarburization degree of 82.7% (decarburization degree [%] =

((Total content of C before the start of the test - total content of C after the end of the test) / total content of C before the start of the test) 100%). The coke in coarse fraction was used up. In the middle of the agglomerate stones examined, relics of fine coke could still be seen. In the diag. 1, the course of the strength St in N / mm ² above the temperature T given in [° C.] is plotted for the agglomerate stones according to the invention investigated in test I. It can be seen that the stones according to the invention have a cold early and cold end strength of more than 20 N / mm ² even at room temperature. The strength of the agglomerate stones increases up to approx. 300 ° C and then remains at a level in the range of around 20 N / mm ² up to a temperature of 850 ° C. The strength then drops only from 850 ° C, but is still above 3 N / mm ² at 1000 ° C.

For comparison is in Diag. 2 for agglomerate stones produced in a conventional manner using residues, the course of the strength St is also plotted in N / mm ² above the temperature T given in ° C. It can be clearly seen that the cold early and cold end strength at room temperature is only in the range of 12 N / mm ² and remains in this range up to 210 ° C. Only when the temperature continues to rise does the strength St increase briefly to approximately 22 N / mm ² in the range up to approximately 400 ° C. Subsequently, however, the strength St drops again so much that it only reaches 2 N / mm ² at 900 ° C. In Diag. 3a the line "KS" plots the temperature profile in ° C. of an agglomerate stone KS with the composition used for experiment I over the heating time t _h given in minutes. In addition, the "HK" line plots the stone temperature over the heating-up time for an HK agglomerate stone in which charcoal was used as the carbon carrier instead of coke dust, but which otherwise corresponds to the agglomerate stones examined in Experiment I. There are only slight deviations from both courses.

In Diag. 3b is the weight loss dG, which occurs in g as the heating time t _{h increases} , of the agglomerate stones (line "KS") produced using coal dust and tested in experiment I (line "KS") and that produced using charcoal as a carbon carrier, but otherwise with those in the experiment I matching agglomerate stones (line "HK") again applied over the heating time t _h . Here, too, there are only slight deviations from the two courses.

Finally, in Diag. 3c the decrease in the height H _s of the agglomerate stones examined in experiment I (line "KS") and with the use of charcoal as a carbon carrier, which occurs with increasing heating-up time t _h , but otherwise with the agglomerate stones corresponding to experiment I (line "HK" ) also plotted over the heating time t _h . Again, there are only slight deviations from the two courses.

The diagrams 3a - 3c show by the observed change in the increase in the stone temperature T _s , the height H _s and the weight loss dG of the agglomerate stones KS and HK, that metallization begins at temperatures above 800 ° C. This process can be observed independently with both investigated carbon carrier materials (coke dust, charcoal). The support structure that forms as a result of the metallization counteracts the drop in strength that occurs at high temperatures, so that up to the area of a blast furnace where the solid material becomes plastic on its way down due to the ever higher temperatures ("cohesive zone") sufficient strength of the agglomerate stones is guaranteed for the gasification and locomotion.

Trial II

In the second experiment, iron ore dust is initially from a concentrate that came from the Carol Lake, Canada deposit, with a grain size of up to 500 μm and a hematite / magnetite ratio of 1: 1 with coke dust as a carbon carrier and a quick-setting one , standard commercial cement has been mixed as a cement binder. The mixture obtained contained (in% by weight) 70 to 80% iron ore dust, 10 to 15% coke dust and 10 to 15% cement. Agglomerate stones were produced from the mixture composed in this way in the manner already explained for experiment I.

The agglomerate stones obtained in this way were also subjected to the modified RuL test. The degree of reduction was 95.6% and the degree of decarburization was 85%. The trivalent iron level was completely reduced. For comparison, primarily iron dust consisting of magnetite and a grain size of up to 1 mm from a concentrate, which came from the Guelbs / Kedia deposit, Mauritania, was also mixed with coke dust and quick-setting, commercially available cement binder. In this case too, the iron ore content of the mixture obtained was 75% by weight, its coke content 13% by weight and its cement content 12% by weight.

The agglomerate stones also produced from this mixture in the manner already described in connection with experiment 1 have also been subjected to the RuL test. It gave a degree of reduction of 88.3% and a degree of decarburization of 83.2%.

In further experiments, it was possible to demonstrate that even such agglomerate stones composed according to the invention, which were produced using dust collected in aqueous solution and produced in the production of ore concentrates with grain sizes of up to 7 μm, were metallized in the RuL test at 1100 ° C of 80%.

Claims

P A T E N T AN S P RÜ C H E

Agglomerate stone for use in shaft, Corex or blast furnaces, which (in% by weight) 6 - 15% of a cement binder, up to 20% of a carbon carrier, up to 20% of residual and recyclable materials, optionally up to 10% in a solidification and hardening accelerator, and the remainder in stone-form iron ore in the form of particles with a grain size of less than 3 mm and after three days an early strength of at least 5 N / mm ² and after 28 days a cold compressive strength of has at least 20 N / mm ² .

2. agglomerate stone according to claim 1, d a d u r c h g e k e n n z e i c h n e t, that the iron ore is present in the form of fine or very fine dust.

3. Agglomerate stone according to one of the preceding claims, d a d u r c h g e k e n n z e i c h n e t that the grain of the iron ore is up to 1 mm.

4. agglomerate stone according to any one of the preceding claims, characterized in that the iron ore is present in haematite (Fe ₂ 0 ₃ ), magnetitic (Fe ₃ 0 ₄ ) and / or wuestitic (FeO) modification.

5. agglomerate stone according to one of claims 1 to 4, d a d u r c h g e k e n n z e i c h n e t, d a s s the iron ore in the form of geothite (FeO (OH)) with a grain size of up to 2 mm, in particular less than 2 mm, is present.

6. agglomerate stone according to one of the preceding claims, that a d u r c h g e k e n n z e i c h n e t, that his iron content is at least 40 wt .-%.

7. agglomerate stone according to any one of the preceding claims, d a d u r c h g e k e n n z e i c h n e t, that is the cement binder Portland cement or metallurgical cement.

8. Agglomerate stone according to one of the preceding claims, that is the solidification and consolidation accelerator, water glass, alumina cement, calcium chloride, an alkali salt, in particular a Na salt, or a cellulose adhesive, such as paste.

9. agglomerate stone according to one of the preceding claims, characterized in that its carbon carrier content is 8-15% by weight.

10. Agglomerate stone according to one of the preceding claims, d a d u r c h g e k e n n z e i c h n e t, that the carbon carrier is in the form of coke dust, coke quenching, coke breeze or anthracite coal.

11. Agglomerate stone according to one of the preceding claims, that a d u r c h g e k e n n z e i c h n e t that the grain of the carbon carrier is up to 2 mm.

12. Agglomerate stone according to one of the preceding claims, d a d u r c h g e k e n n z e i c h n e t, that it has a cylindrical, cuboid or polygonal shape, in particular has a block shape with a polygonal, in particular hexagonal base area.

13. Agglomerate stone according to one of the preceding claims, d a d u r c h g e k e n n z e i c h n e t, that he as a green body before it dries has a water content of less than 25%.

14. Agglomerate stone according to one of the preceding claims, characterized in that it achieves a degree of reduction of at least 80%, in particular more than 80%, during the reduction.

15. Use of fine and fine ore in stone format with a grain size of up to 3 mm for the production of agglomerate stones for the production of pig iron.

16. Use according to claim 15, d a d u r c h g e k e n n z e i c h n e t, that the agglomerate stones according to one of claims 1 to 15 are obtained.

17. Use of agglomerate stones procured according to one of claims 1 to 14 in shaft, Corex or blast furnaces.

18. A process for the production of agglomerate stones obtained according to one of claims 1 to 14, in which - iron ore in the form of fine or very fine dust with a maximum grain size of 3 mm with a binder present as a hydraulic cement phase and optionally with a carbon carrier, with Residual and recyclable materials and / or a solidification and solidification accelerator are mixed with the proviso that the proportion of the cement binder in the mixture obtained (in% by weight) is 6-15%, and the proportion of the carbon carrier is up to 20 %, the proportion of residual and circulating substances up to 20% and the proportion of solidification and solidification accelerators up to 10%, - the mixture obtained is filled into molds, - the mixture filled into the molds is pressed, and - The pressed mixture is dried.

19. The method of claim 18, d a d u r c h g e k e n n z e i c h n e t that the mixture is subjected to a shaking movement during the pressing.

20. Process for the production of agglomerate stones obtained according to one of claims 1 to 14, in which • iron ore in the form of fine or very fine dust with a maximum grain size of 3 mm with a binder present as a hydraulic cement phase and optionally with a carbon carrier, is mixed with residual and circulating materials and / or a solidification and solidification accelerator with the proviso that the proportion of the cement binder in the mixture obtained (in% by weight) is 6-15%, and the proportion of the carbon carrier is up to 20%, the proportion of residual and circulating materials up to 20% and the proportion of solidification and solidification accelerators up to 10%, - the mixture obtained is filled into molds, - the mixture filled in the molds is subjected to a shaking movement, and - The shaken mixture is dried.

1. The method of claim 20, d a d u r c h g e k e n n z e i c h n e t, that the mixture is additionally pressed while it is exposed to the shaking movement.