WO1998040524A1 - Method of producing an agglomerate - Google Patents

Abstract

The invention concerns a method of producing an agglomerate from a metal- or metal-oxide-containing fine material and a mineral binder by blending the fine material with a clay-mineral-containing raw material to form a mass, forming individual mass bodies and solidifying the latter to form an agglomerate. According to the invention, in order to process metal- or metal-oxide-containing fine material, in particular roll scale, economically and cheaply, between 2 and 10 mass % of the clay-mineral-containing raw material with a grain size of between 0.5 mu m and 200 mu m is blended with between 98 and 90 mass % of the metal- or metal-oxide-containing fine material, the mass humidity being set at between 6 and 20 %, to form a plastic mass which is conveyed in blocks to a separating tool which divides the mass blocks into individual mass bodies which are then hardened.

Description

 Process for producing an agglomerate

The invention relates to a method for producing an agglomerate from a powdery to coarse-grained metal or metal oxide-containing fines and a mineral binder by mixing the fines with a clay mineral-containing raw material to form a mass, forming individual mass bodies and solidifying them to form an agglomerate.

In particular, the invention relates to a method of the type mentioned for producing an agglomerate from scale obtained in rolling mills, in particular oil-containing scale scale.

The economical processing of mill scale into agglomerates, which can be fed to a blast furnace process as iron or iron oxide carriers, is of particular importance because of the large quantities of mill scale that arise. As is known, in the hot forming and heat treatment of steels, iron oxides form on the steel surfaces, the so-called mill scale, which is preferably fed to an iron and steel extraction process in order to recover its iron content.

For economic and metallurgical reasons, furnace process, however, only iron oxides in question, which are free from undesirable accompanying elements and have sufficient pressure resistance and abrasion resistance as hardened agglomerates. Known mill scale agglomerates, such as known from DE 31 49 013 A1 in the form of concrete-like products using a hydraulic binder, meet these requirements only inadequately, so that the scale that is still present is often simply stored outdoors in so-called landfills becomes. The resulting mill scale is generally highly oil-containing. For the production of agglomerates, it is therefore popular to use processes with controlled heat treatment in order to burn off the proportion of hydrocarbons. Such a heat treatment of powder molded parts, which are preferably pre-pressed from mill scale, repeatedly leads to the breaking of individual molded parts, with the result that the reject fraction, in particular the dust emission, is high.

From DE 196 29 099 A1 it is also known to form the generally powdery mill scale with the addition of a mineral binder, in particular a raw material containing clay minerals, as a ceramic molded body which is then dried and fired. However, the proportion of clay mineral-containing raw material required for the formation of ceramic moldings is too high to meet the purity requirement of iron oxide without undesired accompanying elements. A reduction in the proportion of raw material containing clay minerals to less than 10% by mass has so far not led to any usable agglomerates, since the shaped bodies produced from such mill scale mixtures do not have sufficient stability for a subsequent hardening process. The addition of additional strengthening materials fails due to the requirement to keep accompanying elements in the agglomerates as low as possible.

The object of the invention is therefore to provide a method for producing an agglomerate from a powdery to coarse-grained metal or metal oxide-containing fine material, in particular mill scale, according to the preamble of claim 1, the procedural steps of which are adapted to the quality requirements and inexpensive, economical processing - allow the mill scale.

This object is achieved by the features of the characterizing part of claim 1.

In this way, a method is created which, through the preparation according to the invention of a mass made of a metal or metal oxide-containing fine material, in particular mill scale, and clay mineral-old raw material, permits the setting of a plasto-viscous mixture consistency with only a small amount of aggregate containing clay mineral. The high moisture content in relation to the proportion of clay mineral-containing raw material has an advantageous effect, which leads to clay slip-like conditions, with the result that the fine material particles are combined in the agglomerate via a finely divided silicate mineral sinter matrix.

Because the mass is transported in blocks, it is portioned into masses in which the mass is left largely at rest. The behavior of the mass caused by the clay is maintained in this way in a portioning process. Due to the fact that the mass blocks are then only divided, that is to say the inner rest of the mass is largely maintained even when shaping to mass bodies, mass bodies are obtained whose plastoviscosity gives the mass body sufficient stiffness. The mass bodies formed therefore have good stability against puncture and embossing loads and for the further treatment process such as the hardening process. The mass treatment is therefore carried out under low process loads.

The mass bodies are further preferably thermally treated with a residual moisture content of greater than or equal to 3%. The mass bodies can therefore be placed in a firing unit entirely without or without extensive drying. The heat of vaporization of the water has a positive effect on the reduction of thermal voltages. The mass bodies therefore show a structure-related and textural higher resilience to thermal stress. chung.

In particular, the hydrocarbon-enriched fine sludge, which is produced in the steel rolling process and in the steel processing industry and has previously been deposited, can be agglomerated in this way and then recycled.

Further refinements of the invention can be found in the following description and the subclaims.

The invention relates to a method for producing an agglomerate from a metal or metal oxide-containing fine material and a mineral binder by mixing the fine material with a clay mineral-containing raw material to form a mass, forming individual mass bodies and solidifying the same to form an agglomerate.

The fine material is preferably scale produced in rolling mills, in particular oil-containing mill scale. The mill scale to be agglomerated can be added with particle grain sizes in the fine to coarse grain range, with up to 50 Ma in the grain size range between 1 and 10 mm. The mill scale can also be up to 90% powdery fines, i.e. with grain sizes up to ^ 100 μm ^ can be added.

90 to 98% by mass of the mill scale are mixed with 2 to 10% by mass of a raw material containing clay minerals in the grain size 0.5 μm to 200 μm with setting a mass moisture of 6 to 20% to a doughy mass. The desired moisture content can be adjusted depending on the moisture content of the metallic or metal oxide fines, possibly its oil content, as well as the moisture content of the clay mineral raw material by removing or adding water. The mill scale is generally in a puncture-resistant, gritty / muddy, at least grain-digested form. The proportion of mill scale in the batch can be partially replaced by another metal-containing fine material, such as, in particular, metallic grinding dust or chips.

The clay mineral-containing raw material is preferably added in very fine-grained form, in particular in the grain sizes 0.5 μm to 80 μm, with 50 to 80% of the proportion of the clay mineral-containing raw material preferably being added in the grain size between 20 and 60 μm. Furthermore, the clay mineral-containing raw material is preferably added with an essentially continuous grain size distribution.

The clay mineral-containing raw material preferably contains one or more two- and / or three-layer clay minerals as the main constituent. Clays whose cation exchange capacity is increased due to an at least low degree of diagenesis are preferred as two-layer clay minerals.

0.3 to 1.5% by mass of additional strengthening substances, such as inorganic thickeners, in particular water glass, sugar solution, aluminum chromate or a phosphate, can be added to the mixture of mill scale and clay mineral-containing raw material. Minor proportions, preferably up to 0.5% by mass, of organic additives, in particular molasses, can also be added. Another additive to lower the hardening temperature are low-melting silicate substances, such as, in particular, a glass powder or phonolite, which can replace the raw material containing clay minerals up to 10 to 40% of its proportion when mixed with mill scale.

The mixing of the batch into a doughy mass, in which the incorporated air is generally distributed over the smallest gas bubbles, is preferably carried out by means of a twin-shaft mixer. After the offset has been mixed into a mass, the mass is transported in blocks to a cutting tool, which divides the mass blocks into individual mass bodies, which are then hardened. The mass is not earned at all or only marginally when transported in blocks. tet.

Before the mass is fed to this blockwise transport, its processing consistency, i.e. their moisture content is checked again using water as the correction medium. This ensures that the mass with the desired mass moisture of 6 to 20% can get into a loading device for block transport.

The mass is preferably transported in blocks using a piston press which is only subjected to low pressures. Depending on the moisture content of the mass, the applied pressures are between 0.4 and 2.5 MPa.

An outlet nozzle of the piston press can divide the mass transported in blocks into individual rods, from which individual mass bodies can be sheared off. Alternatively, the mass transported in blocks can be ejected in Hubein and then go through a stamping and / or embossing process.

It is always crucial that the mass is not subject to a mixing process during the shaping process, which would lead to the destruction of the stability of the mass.

The individual mass bodies are then thermally treated with a residual moisture content of greater than or equal to 3%. The mass bodies are preferably brought directly into a firing unit without drying. The thermal treatment serves to harden the mass bodies to form agglomerates, the hardening preferably being based on a sintering process with the formation of a silicate sintering matrix which has a glass phase and optionally a crystalline phase, in particular a mullitic phase. The silicate sinter matrix is then a glassy matrix in which crystalline particles are embedded, which are preferably a primary mullite. The hardening process is preferably carried out by means of a thermal treatment at temperatures between 800 and 1200 ° C and a holding time of less than 90 min, so that the clay mineral-containing raw material can form a melting phase, which preferably consists of a glassy solidified sintered matrix with a crystalline fraction, in particular granular mullite or Primary mullite, in which the mill scale particles are embedded. The mass bodies are preferably fed directly to this baking firing, so that the heating phase lies in the initial phase of the baking firing. During this initial phase of the cooking or sintering firing, the mass bodies are given an outer, load-bearing crust, which leads to such inherent stability that the mass bodies can even be fired in a roller furnace.

With the process described above, agglomerates with a proportion of more than 90% by mass of mill scale and a silicate mineral sinter matrix can be produced, the structure of which gives the agglomerate a high pressure and abrasion resistance.

Since the mass is not or only slightly compressed during block-by-block transport and the mass bodies only contain slurry-like amounts of mineral binder in terms of moisture content, larger pore spaces remain after firing, due to the removal of moisture and the particle structure occupied by the mill scale particles. The essentially glassy binder, preferably clay, is not sufficient to fill the cavities of the mill scale particle framework. Due to the processing, however, the solidifying silicate melt with mineral precipitation forms molten skins around the mill scale particles as well as fusible links between the mill scale particles, which leads to a reliable compacting of the mill scale grains. This gives mass bodies which have a desired, preferably high porosity after the hardening process.

Foaming effects due to the introduction of moist mass bodies into the cooking firing and the escaping water vapor can also reduce the porosity. if increase.

Even after wet sintering, the agglomerate therefore has a pore fraction of the total volume of 20 to 50% by volume, in particular 35 to 45% by volume, more than 60% of this porosity being formed by an open porosity. Despite the compacting of the mill scale particles by means of a liquid phase, the proportion of open porosity is between 75 and 95%.

The above statements apply accordingly if metal powder, metallic grinding dusts and / or metal chips are used as the metal or metal oxide-containing fine material, which are preferably mixed with the mineral binder in fine-grained form and are processed into agglomerates as described above.

The shape of the agglomerate can be selected and can take on flat or rounded shapes.

The agglomerate is preferably given a punching or piercing body shape with a crater depth on the head side via a shaping process. The crater depth can make up to 70% of the total height of the body shape. Crater depths of 50 to 60% of the total height are preferred. The crater depth can have funnel widths of 50 to 80% of the total diameter or the total length of the agglomerate. The crater depth is also preferably formed centrally on the body so that the agglomerate has wall thicknesses that are as uniform as possible. Such a shape has a larger body surface and causes a change in the core tension, so that core cracks occur less frequently. Such a body shape also shortens the thermal treatment required.

Claims

claims 1. A process for producing an agglomerate from a powdery to coarse-grained metal or metal oxide-containing fines and a mineral binder by mixing the fines with a clay mineral-containing raw material into a mass, forming individual mass bodies and solidifying them to form an agglomerate that is used as a blast furnace feed characterized in that 2 to 10% by mass of the clay mineral-containing raw material in the grain size 0.5 μm to 200 μm are mixed with 98 to 90% by mass of the metal or metal oxide-containing fine material with setting a mass moisture of 6 to 20% to a doughy mass which is transported block by block to a cutting tool that divides the mass blocks into individual mass bodies, which are then hardened. 2. The method according to claim 1, characterized in that as the metal or metal oxide containing fines a mill scale, especially oil-containing mill scale, is used with fine and / or coarse particles. 3. The method according to claim 2, characterized in that the mill scale is added with up to 50% of the grain in the coarse-grained area greater than or equal to 1 mm and less than or equal to 10 mm. 4. The method according to claim 2 or 3, characterized in that the mill scale is added with up to 90% as a powdery fine material with grain sizes 4: 100 microns. 5. The method according to any one of claims 2 to 4, characterized in that the proportion of the mill scale in the batch is partially replaced by another metal or metal oxide-containing fines. 6. The method according to claim 1, characterized in that the metal or metal oxide-containing fine material consists of metal powders, metallic grinding dusts and / or metal chips. 7. The method according to any one of claims 1 to 6, characterized in that the cutting tool divides the mass transported in blocks into individual strands, from which the individual mass bodies are sheared off. 8. The method according to any one of claims 1 to 6, characterized in that the cutting tool divides the mass transported in blocks by punching into individual mass bodies. 9. The method according to any one of claims 1 to 8, characterized in that the clay mineral-containing raw material is added in the grain size 0.5 microns to 80 microns. 10. The method according to any one of claims 1 to 9, characterized in that 50 to 80% of the proportion of the clay mineral-containing raw material in the grain size between 20 and 60 microns is added. 11. The method according to any one of claims 1 to 10, characterized in that the mass bodies for a sintering process with a residual moisture content of ^ 3% are brought into a firing unit for a bake. 12. The method according to claim 1 to 10, characterized in that the mass is broken down into blocks by means of a piston press. 13. The method according to claim 12, characterized in that the applied compression pressures are between 0.4 and 2.5 MPa depending on the moisture content of the mass. 14. The method according to any one of claims 1 to 13, characterized in that the clay mineral-containing raw material is added with an essentially continuous grain size distribution. 15. The method according to any one of claims 1 to 14, characterized in that the clay mineral-containing raw material contains one or more two-layer clay minerals as the main component. 16. The method according to claim 15, characterized in that such clays are added as two-layer clay minerals whose cation exchange capacity is increased due to an at least low degree of diagenesis. 17. The method according to any one of claims 1 to 16, characterized in that 10 to 40% of the proportion of clay mineral-containing raw material to be mixed with the metal or metal oxide-containing fine material is replaced by low-melting silicate substances. 18. The method according to claim 17, characterized in that glass powder or phonolite are used as the low-melting silicate substance. 19. The method according to any one of claims 1 to 18, characterized in that the mixture of clay mineral-containing raw material and metal or metal 1-oxide-containing fines 0.3 to 1.5% by mass of an admixture additive is added from an inorganic thickener. 20. The method according to claim 19, characterized in that a silicate, in particular water glass, an aluminum chromate or a phosphate is used as an inorganic thickener. 21. The method according to any one of claims 1 to 20, characterized in that the mass body is introduced directly into a cooking firing. 22. The method according to any one of claims 1 to 21, characterized in that the mass body at a temperature of 800 - 1200 ° C and a total treatment time of 20 to 90 min. is thermally treated. 23. Agglomerate according to the method according to one of claims 1 to 22, characterized in that the powdery to coarse-grained metal or metal oxide-containing fine material is embedded in a sintered matrix of a glassy solidified silicate melt with mineral precipitation at a porosity of 20 to 50% by volume Total volume, the proportion of open porosity is 75 to 95%. 24. Agglomerate according to claim 23, characterized in that the mineral excretion of embedded, crystalline inclusions is formed from a primary gauze. 25. Agglomerate according to claim 23 or 24, characterized in that the metal or metal oxide-containing fine material is a granular mill scale. 26. Agglomerate according to claim 25, characterized in that the granular mill scale with fine to coarse grain mill scale particles is embedded in the sinter matrix, with up to 50% of the proportion of mill scale mill scale particles in the grain size range between 1 and 10 mm. 27. Agglomerate according to claim 25, characterized in that the granular mill scale up to 90% consists of mill scale particles with a grain size of less than 1 mm. 28. Agglomerate according to claim 23 or 24, characterized in that the metal or metal oxide-containing fine material consists of metal powder, metallic grinding dusts and / or metal chips. 29. Agglomerate according to one of claims 23 to 28, characterized in that the agglomerate has a punching or piercing shape with a head-side crater depth.