SK769087A3 - Method and device for creation metals or metal alloys - Google Patents

Description

METHOD OF OBTAINING METALS, WHETHER METAL ALLOYS, AND DEVICE FOR CARRYING OUT THIS METHOD

Technical field

The invention relates to a process for obtaining metals or metal alloys, in particular for obtaining ferro-alloys, by reducing metal oxides in a reduction zone formed by a layer of coal through which a reducing gas flows and to an apparatus for carrying out the process.

BACKGROUND OF THE INVENTION

EP-A-0 174 291 discloses a method for smelting metals, namely copper, lead, zinc, nickel, cobalt and tin, from oxidic, fine-grained non-ferrous ores, wherein the feed material is introduced into a reduction zone which it consists of a whirling layer of coal in the melter gasifier. Upon passing through this reduction zone, the oxidic feed material is reduced to a metal that collects at the bottom of the melter gasifier.

It has been shown that the process according to EP-A-0 174 291 can be advantageously used for the reduction of oxides which react with elemental carbon at temperatures below 1000 ° C, but that there may be problems in obtaining metals and metal alloys, in particular ferro-alloys, such as ferro-manganese, ferrochromium and ferro-silicon, which can be obtained from their oxides at temperatures above 1000 ° C and elemental carbon as reducing agent, since the contact time of these batch oxidizing materials reacting at high temperatures with the coalescing particles is relatively short.

The present invention has been attempted to avoid these problems and difficulties and has the object of developing a method and apparatus of the type described above which would make it possible to produce metals and metal alloys, especially ferroalloys such as ferro-manganese, ferrochromium and ferro-silicon. wherein the metal would have such a high affinity for oxygen that it would react with elemental carbon at temperatures above 1000 ° C.

SUMMARY OF THE INVENTION

This object is achieved by the method according to the invention such that the coal layer is formed of three solid layers, wherein:

the bottom layer covered with the reduced metal-slag liquid mixture is degassed coal, oxygen or oxygen-containing gas is introduced into the middle layer to form a hot reducing gas consisting essentially of carbon monoxide; at a distance, a fine-grained oxide feed material is introduced into the middle layer and combustion gases from coal particles and oxygen, optionally from oxygen-containing gas, are introduced into the upper layer.

Preferably a fine-grained oxidic feed material with a grain size of up to 6 mm is used.

Preferably, coal with a particle size of 5 to 100 mm, in particular 5 to 30 mm, is used to form the solid layer.

In a preferred embodiment, the thickness of the middle and upper solid layers is maintained at 1 to 4 m.

Another embodiment of the invention is characterized in that the pulverized coal particles are separated from the waste gases of the reduction zone and the separated coal particles, preferably in the hot state, are fed together with oxygen or oxygen-containing gas into burners which are directed to the upper part of the solid. layers.

The coal-free waste gas can be used as a carrier medium for the finely divided oxide feed material.

Preference is given to using coal which, after degassing, retains its lumpy character, so that for a grain size range of 5 to 100 mm, preferably 5 to 30 mm, after degassing at least 50% of the degassed coal produced has an initial particle size of 5 to 100 mm. 5 to 30 mm and the remainder has the smallest grain.

The advantage of the process according to the invention is that it retains all the known advantages of the reduction process in shaft furnaces heated by fossil energy, such as countercurrent heat exchange, metallurgical reaction in a solid elemental carbon layer, which is essential for reducing non-noble metal oxides and good metal separation from slag. The jumping or degassing of the coal can be carried out without the formation of tar and other condensable compounds. The gas produced during the degassing of coal acts as an additional reducing agent together with the reducing gases produced by the gasification of the degassed coal.

The oxidic material used can, in a particular case of carrying out the process according to the invention, be pre-reduced in the pre-reduction step, which appears to be advantageous in the production of ferroalloys, where the iron oxide content of the feedstock is accessible by this reduction.

A particular advantage of the process according to the invention is that reduction of oxides of non-noble elements such as silicon, chromium and manganese can be carried out without the use of electrical energy. In the process according to the invention, the energy required for the degassing of coal is simply controlled, since the smallest grain (below 5 mm) is discharged with the hot gases from the melter gasifier into the upper breathing zone of the oxygen-containing gases and oxidized by the oxygen-containing gases.

The grain disintegration is tested by subjecting the coal fraction having a grain size of 16 to 20 mm to a 1 hour degassing in a preheated chamber to a temperature of 1400 ° C. The volume of the chamber is 12 dmS. After cooling by purging with cold inert gas, the grain size distribution is determined.

The invention also relates to an apparatus for carrying out the method according to the invention with a shaft melter gasifier and having a refractory lining having an inlet opening for coal inlet and a gas outlet pipe at the top, a shaft melter gasifier in the side wall having a feed for coal particles and oxygen. optionally for an oxygen-containing gas and at the bottom is equipped to collect molten metal and liquid slag. This device is characterized in that by forming three superposed rigid layers A, B, C:

in the region between the lowermost solid layer A and the middle layer B there is arranged a blower ring for oxygen or oxygen-containing gas, at a distance above the blower ring there is a blower ring for fine-grained oxidic charge material and at a distance above it in the region the upper solid layer C is a ring of burners for a gas containing coal particles and oxygen, or an oxygen containing gas.

Preferably, the gas removal line is connected to an irradiating cyclone for separating coal particles from the waste gas, and the discharge end of the hot cyclone is connected to the rim of the burners through the line.

In a particular embodiment of the device according to the invention, the hot cyclone is connected via a conduit to another hot cyclone, and into the connecting conduit between the two hot cyclones a metering device for the oxidic feed material flows; the discharge end of the next hot cyclone is connected via a conveying line to the fan ring for the oxidic feed material.

Image overview

The method according to the invention or the apparatus for carrying out the method according to the invention are explained in more detail in the drawings, wherein:

FIG. 1 is a schematic representation of a melter gasifier with an attachment attached thereto, and FIG. 2 is the temperature profile of the melter gasifier.

DETAILED DESCRIPTION OF THE INVENTION

The shaft melter 1 is equipped with a refractory lining 2. The bottom region of the shaft melter 1 serves to collect molten metal 3 and molten slag 4. At the bottom there is a tap hole 5 for metal and a tap hole 6 for slag. In the upper part of the shaft melter gasifier 1 there is an inlet opening 7 for adding lump coal. Above the liquid layer of molten metal 3 and molten slag 4 a formed layer of coal is formed, namely the bottom layer A of degassed coal, which does not conduct gas, the middle layer B of degassed coal, which conducts gas and the upper layer C of lump coal. gas.

In the side wall of the shaft melter gasifier 1 there are blowers in the form of a ring of blowers 8 for oxygen or for oxygen-containing gases. These blowers are disposed in the region between the gas-free lowermost layer A and the intermediate layer B. At a distance, the rim of the jet-shaped blowers 9 through which the fine-grained oxidic feed material flows into the middle layer B are spaced.

In the boundary region between the middle layer B and the upper layer C there is a ring of burners 10 in the side wall of the shaft melter gasifier 7 into which a mixture of pulverized coal and oxygen particles or oxygen-containing gas is introduced. From the upper part of the shaft melter gasifier 1, the generated waste gas is conveyed to the hot cyclone 12 by the duct 11. The pulverulent coal particles suspended in the waste gas are separated in the hot cyclone 12 and from the discharge end of the hot cyclone 12. The piping 15 introduces the oxygen-containing gas into the burners 10. The metering device 13 can control the filling of the hot cyclone 12 and thus the separation action of the hot cyclone 12 can be influenced.

From the top of the hot cyclone 12, the conduit 16 leads to another hot cyclone 17. The metering device 18 into which the fine-grained oxide feed material from the container 19 is fed is connected to the connecting pipe 16. The gas in the connecting pipe 16 has the function of a carrier gas. From the discharge end of the hot cyclone 17, the fine-grained oxidic feed material is fed into the conveying line 20 and from there it is fed via the line 21 to the blowers 9.

From the upper end of the hot cyclone 17 a conduit 22 leads through which excess waste gas is discharged. It can be cooled and compressed and blown through line 23 as a transport environment into line 21.

The process according to the invention is preferably carried out in that the coal introduced into the upper part of the shaft melter gasifier 1 is degassed in the solid layer C. The heat required for this degassing is obtained both from the hot reducing gases rising from the solid layer B and the combustion heat of the solid coal particles which are combusted by the oxygen-containing gas in the burners W. The vertical distribution of the layer C is chosen such that the gases leaving the layer C have a temperature of at least 950 ° C. This ensures the cracking of tars and other condensable compounds. This avoids clogging of the solid layer C. In practice, a thickness of 1 to 4 m for the layer C is proven. The vertical distribution of the 1 to 4 m layer also proves to be good for solid layer B. In layer C, the degassed coal forms a solid layer B as it falls downwards.

The fine granular oxidic feed material is pre-reduced in the hot cyclone 17 by hot reducing gas and drift and is separated from the gas again. The introduction of fine-grained carbon-containing dust into the hot reducing gas may be advantageous because the carbon reacts with the carbon dioxide formed in the reduction to form carbon monoxide, thereby retaining the reducing nature of the hot gas in the shaft melter E The separated fine-grained oxidic feed material melts in layer B and is reduced by elemental carbon. The heat required for melting and reduction is obtained by gasifying hot degassed coal with oxygen-containing gas, which is introduced by blowers 8 into the shaft melter gasifier L in solid layer B, the molten metal formed and the molten slag flow down and collect in layer A and tap.

In FIG. 2, the temperature profile is the height of the shaft melter gasifier 1, the ordinates showing the height ratios and the x-axis of the temperature. The fully marked line indicates the temperature profile of the added coal and the dashed line indicates the temperature profile of the gas produced. The height on the y-axis is indicated by the number 8. '.:;? blower ring 8, height 9 denotes blower level 9 for fine-grained oxidic feed material (ore), height 10 denotes the re-introduction of carbon particles by burners 10, height 24 denotes the upper limit of solid layer 24, and height 11 denotes height a gas outlet pipe 11 or a coal inlet 7, respectively.

The invention is illustrated in more detail by way of example. Percentages are always by weight.

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Example

The procedure is as described above. The ore is a fine-grained manganese ore with a particle size of not more than 10 mm, containing approximately 42% of manganese. The ore has the following composition:

Fe 5,7%

CaO 11,8%

MgO 2,2%

S1O2 5.2%

AI ₂ O ₃ 0.1%

MnO 53,2%

CO ₂ 17.9%

H ₂ O 1.5%

Medium volatile bituminous coal of the following approximate composition is used as fuel:

% C _fix

25%%

volatile fractions ash water

The diameter of the coal particles is 1 to 40 mm. Per tonne of ferro-manganese 75% is used

750 kg of coal. Ferromangan analysis revealed:

Mn 75.0% C 7.0% Are you 0.8% WITH 0.02%

The oxygen consumption per tonne of ferro-manganese is 950 Nm ⁸ and the gas consumption per tonne of ferro-manganese is 3 200 Nm ⁸ with a calorific value of approximately 2 000 cal per Nm ⁸ .

Claims (9)

PATENT CLAIMS Method for obtaining metals or metal alloys, in particular ferro-alloys, by reducing metal oxides in a reduction zone formed by a layer of coal through which a reducing gas flows, characterized in that the layer of coal consists of three solid layers A, B and C, where ----------- QL · - lower layer A covered with a liquid mixture of reduced metal and slag is from degassed coal, - oxygen or oxygen-containing gas is introduced into the middle layer B to form a hot reducing gas consisting essentially of carbon monoxide and spaced into the middle layer B introduces fine-grained charge material and combustion gases from coal particles and oxygen, or oxygen-containing gas, are introduced into the upper layer C. Method according to claim 1, characterized in that an oxidic fine-grained charge material with a particle size of up to 6 mm is introduced. Method according to claims 1 and 2, characterized in that coal having a grain size of 5 to 100 mm, in particular 5 to 30 mm, is used to form solid layers A, B, C. Method according to claims 1 to 3, characterized in that the thickness of the middle and top layers is 1 to 4 m. Method according to one of Claims 1 to 4, characterized in that pulverized coal particles are separated from the off-gas from the reduction zone and the coal particles, preferably in the hot state, are introduced together with oxygen or oxygen-containing gas into the burners directed to upper solid layer C. Method according to claim 5, characterized in that the coal-free off-gas is used as a carrier medium for the fine-grained oxidic feed material. An apparatus for carrying out the method according to claim 1 to. 6, comprising a shaft melter gasifier (1) having an inlet opening (7) for adding coal and a gas outlet pipe (11) at the top, having a carbon particle and oxygen or oxygen containing gas pipe in the side wall; having a lower portion for collecting the molten metal (3) and the molten slag (4), characterized in that, with the formation of three superposed solid layers A, B, C - __, it is in the region between the lowermost solid layer A and the middle layer B a blower ring (8) arranged for oxygen or oxygen-containing gas, ----------- spaced above the blower ring (8) is a blower ring (9) for the finely divided oxidic feed material, and-- ---------—---------- at a distance above the crown of the blowers (9) for the finely divided oxidic feed material in the region between the middle layer B and the upper solid layer C is a ring of burners (10) for gas containing coal particles and acid the optionally oxygen-containing gas. Apparatus according to claim 1, characterized in that the conduit (11) has a built-in hot cyclone (12) for separating coal particles from the off-gas, the discharge end of the hot cyclone (12) being connected via a conduit to the crown of gas burners (10). containing coal and oxygen particles or an oxygen-containing gas. Apparatus according to claim 8, characterized in that the hot cyclone (12) is connected via a conduit to another hot cyclone (17), and a metering device (18) flows into the connecting line (16) between the two hot cyclones (12, 17). ) for the oxidic feed material and the discharge end of the next hot cyclone (17) is connected via a conveying line (20) to the blower ring (9) for the oxidic feed material.