WO2013091847A1 - Smelting cyclone and apparatus provided with such a smelting cyclone - Google Patents

Abstract

The invention relates to a smelting cyclone for the production of pre-reduced molten iron oxides, wherein the smelting cyclone is provided with a first and second opening, the first opening serving as an inlet for reducing process gas and as an outlet for molten pre-reduced iron oxides and the second opening serving as an outlet for process gas, with supply means to supply iron ore into the smelting cyclone and with supply means to supply oxygen into the smelting cyclone, wherein additional heating means are provided to prevent solidification of molten iron oxides at the outlet of the smelting cyclone.

Description

SMELTING CYCLONE AND APPARATUS PROVIDED WITH SUCH A SMELTING CYCLONE

The invention relates to a smelting cyclone and an apparatus provided with a smelting cyclone.

In steel manufacturing smelting cyclones can be used in the pre-reduction and melting of iron ore. In this context iron ore is defined as metalliferous material containing iron oxides. Such a smelting cyclone is provided with means to inject iron ore and means to inject oxygen from a number of locations around the circumference of the cyclone. The iron ore and oxygen are injected in an about tangential direction therewith generating a vortex or whirling flow inside the cyclone. At the same time a reducing process gas is introduced into the cyclone which in combination with the injected oxygen is partly combusted resulting in sufficiently high temperatures to melt the iron oxides. The vortex or whirling flow in the cyclone promotes mixing of the injected oxygen and the reducing process gas and also heat exchange with the iron oxides. As a result of the swirl motion, iron ore particles and molten iron ore are separated from the gas and collect on the wall of the cyclone wall from where they flow downward to accumulate in a vessel where final reduction takes place. Such smelting cyclones are known for instance from EP0726326 and EP0735146.

A pilot plant with a nominal capacity of 60,000 tonne per year was built in 2010-

2011 to test the combination of a smelt cyclone and a smelting vessel for pig iron production. This pilot plant, constructed on the basis of best available understanding at the time, did not anticipate any particular difficulty in terms of getting molten material from the smelt cyclone to flow downwards into the smelting vessel below. However, in practice, there were unexpectedly persistent cases of solidified material forming at the bottom of the smelt cyclone. On occasion these solidified accretions restricted gas flow between the smelting vessel and the cyclone, giving rise to process disturbances which forced the plant off-line.

Subsequent analysis of this unanticipated plant feature revealed that the temperature inside a smelting cyclone in operation was variable and, in particular, became too low at times in the lower part of the smelting cyclone, where the molten iron oxides flow from the smelting cyclone into the metallurgical smelting vessel. This resulted in cooling and solidification of molten material which had been formed higher up inside the smelting cyclone.

It is an objective of the present invention to provide a smelting cyclone with a sufficiently high temperature that solidification of molten iron oxides in the smelting cyclone is prevented.

It is another objective of the present invention to provide a smelting cyclone with additional heating means to prevent solidification of molten iron oxides in the smelting cyclone.

It is another objective of the present invention to provide oxygen gas injection means as additional heating means.

It is still another objective of the present invention to provide oxygen gas injection means wherein combustion of a pre-reducing process gas by this additional heating means and the further combustion of a pre-reducing process gas in the smelting cyclone are balanced.

It is still a further objective of the present invention to provide an apparatus comprising a metallurgical vessel with a smelting cyclone with additional heating means to prevent solidification of molten iron oxides in the smelting cyclone.

According to a first aspect of the invention one or more of the above objectives are realized by providing a smelting cyclone for the production of pre-reduced molten iron oxides, wherein the smelting cyclone is provided with a first and second opening, the first opening serving as an inlet for reducing process gas and as an outlet for molten pre-reduced iron oxides and the second opening serving as an outlet for process gas, with iron ore supply means to supply iron ore into the smelting cyclone and with oxygen supply means to supply oxygen into the smelting cyclone, wherein additional heating means are provided to prevent solidification of molten iron oxides at or near the first opening of the smelting cyclone and wherein the additional heating means comprise one or more oxygen injectors that in operation inject oxygen from a location below the first opening of the smelting cyclone in a direction such that the injected oxygen will come into contact with process gas entering the first opening.

According to a further aspect of the invention it is provided that the one or more oxygen injectors are positioned outside the circumference of the first opening as seen in vertically downward direction. The term "oxygen" as used in the description could mean an oxygen containing gas as well as pure oxygen.

The temperature near the first opening of the smelting cyclone will still be sufficiently high to have at least part of the pre-reducing gas combust with the injected oxygen. In order to have a high enough temperature at the first opening to prevent solidification of the molten iron oxides at said first opening of the smelting cyclone only part of the pre-reducing gas otherwise combusted inside the smelting cyclone will be needed.

In most cases the smelting cyclone will be a device with a cylindrical shaped passageway with opposite first and second openings wherein the iron ore and oxygen are injected in a central part of the device in a more or less tangential direction to generate the vortex or whirling flow inside the smelting cyclone. In operation the smelting cyclone is usually positioned such that there is a vertical passage from the first opening to the second opening. With such a positioning of the smelting cyclone the combustion of part of the pre-reducing gas at or near the first opening of the smelting cyclone will also contribute in keeping the temperature inside the smelting cyclone at the location where the iron ore is injected at a target value.

According to a further aspect it is provided that the oxygen injectors are arranged such that in operation the oxygen is injected in a direction which is at least partially in line with the direction of flow of process gas entering the smelting cyclone. With the term "oxygen injectors" one or more oxygen injectors is meant unless it is clear from the description that explicitly a single injector or multiple injectors are meant.

The direction of gas flow inside the smelting cyclone is a combined round-going and up-going movement wherein the up-going movement is generated by the pre- reducing gas entering the smelting cyclone and generated heat. Depending on the flow velocity of the pre-reducing gas in upward direction and the distance from which the oxygen is injected with respect to the first opening of the smelting cyclone the oxygen could be injected in a direction anywhere between a direction into the first opening to a direction parallel to a plane perpendicular to an imaginary vertical centre axis of the first opening. Preferably the direction of injection is also given a tangential component meaning that the direction is offset from said vertical axis. By arranging the oxygen injectors in this manner it can be realised that in operation combustion of the injected oxygen and part of the pre-reducing process gas takes place at or near the first opening of the smelting cyclone, resulting in that part of the smelting cyclone being sufficiently heated.

Preferably a number of oxygen injectors are spaced around the circumference of the first opening of the smelting cyclone in order to be able to generate an even heating of the part of the smelting cyclone around the first opening thereof. The spacing of the oxygen injectors around the first opening also comprises that the oxygen injectors are positioned such that these are preferably outside the path of the molten iron oxides coming out of the smelting cyclone. With a vertical positioning of the smelting cyclone this means that the oxygen injectors are spaced around said opening and at a distance from the first opening in both vertical as well as horizontal direction to keep out of the vertical drop trajectory of the molten iron oxides dripping or flowing from the smelting cyclone.

According to a further aspect of the invention it is provided that the oxygen injectors are adjustable such that the direction of injection of the oxygen can be adjusted. The easiest manner to make the direction of injection adjustable is to provide that by rotating at least part of an oxygen injector the direction of injection is changed. In order to do so it is further provided that the axis of rotation of the oxygen injector or injectors and the direction of injection are at an angle with respect to each other. This is realised for example by having a bend in the oxygen injector or by providing a nozzle that directs the injected oxygen at an angle with respect to the axis of rotation of the oxygen injector.

It is further provided that the oxygen injectors are connected to the oxygen supply for the oxygen supply means to supply oxygen into the smelting cyclone. By having a common oxygen supply it is easy to control the total amount of oxygen supplied to the smelting cyclone. Moreover, with such a common oxygen supply the oxygen injectors can be adjusted to inject a fixed percentage of the total amount of oxygen supplied to the smelting cyclone.

According to another embodiment it is provided that the oxygen injectors and the oxygen supply means to supply oxygen into the smelting cyclone are separately adjustable. With such a configuration the oxygen supply can be controlled by adjusting every individual injector which allows to have different amount of oxygen injected by individual injectors or to shut of one or more of the injectors.

According to still another embodiment the oxygen injectors are provided with common flow meter means and common adjusting means to adjust the total amount of injected oxygen. With this setup the total flow of the oxygen injectors can be monitored precisely and adjusted by adjusting a common oxygen supply for all oxygen injectors.

According to still another embodiment the oxygen injectors are connected to an oxygen supply separate from the oxygen supply for the oxygen supply means to supply oxygen into the smelting cyclone. The advantage of such an independent set-up is that the adjusting of the oxygen injectors or the adjusting of the oxygen supply for the oxygen supply means to supply oxygen into the smelting cyclone will have no influence whatsoever on the other supply.

According to still another embodiment separate oxygen supply systems are provided for each individual oxygen injector. This allows a regulation in which the supply of oxygen of each oxygen injector can be totally independent from every other oxygen injector.

According to still a further aspect of the invention also an apparatus for the production of molten iron is provided comprising a metallurgical vessel and a smelting cyclone as described above provided on the top part of the metallurgical vessel and in open connection with the interior of the metallurgical vessel, wherein one or more oxygen injectors extend through the wall of the metallurgical vessel at a position in the region of the first opening of the smelting cyclone.

According to a further embodiment the oxygen injectors extend through the vessel wall spaced around the circumference of the first opening of the smelting cyclone. In combination with such a metallurgical vessel there is ample space and support to mount the oxygen injectors at the right position with respect to the first opening of the smelting cyclone.

According to yet another embodiment oxygen supply means are provided for in the apparatus in at least three zones. These at least three zones comprise a zone in the metallurgical vessel, a zone below the first opening of the smelting cyclone and in the smelting cyclone itself. The distribution is determined on basis of local heating requirements in the apparatus and/or requirements to the reduction potential of the process gas.

The invention will be further explained on hand of the example shown in the drawing, in which:

fig.l shows schematically a smelting cyclone with oxygen injectors below the smelting cyclone;

fig.2 shows schematically a number of oxygen injectors positioned below the first opening of the smelting cyclone at the bottom side thereof;

fig.3 shows a diagram of the oxygen supply system to the smelting cyclone, fig.4 shows a diagram of another oxygen supply system to the smelting cyclone, and fig. 5 shows schematically a smelting cyclone coupled to a metallurgical vessel for the production of molten iron.

In fig. 1 a smelting cyclone 1 is shown schematically with iron ore supply means in the form of a number of iron ore injectors 2 and oxygen supply means in the form of a number of oxygen injectors 3. The number of such injectors will depend on the size of the smelting cyclone but will in any way be more than the number of injectors shown in this figure. These injectors are positioned such that the oxygen and the iron ore are injected with tangential component as much as possible to generate a vortex or swirling motion inside the smelting cyclone.

The smelting cyclone 1 comprises an outer wall 4 against the inside of which a number of water cooled segments 5 are mounted. These water cooled segments 5 have a cooling water inlet 6 and cooling water outlet 7. The smelting cyclone 1 has a cylindrical shape with a circular cross section with a first opening 8 at the bottom side and a second opening 9 at the top side. Instead of the cylindrical shape shown in the figure the smelting cyclone can also have a prismatic shape, for instance a right rectangular prismatic shape. In this example the second opening 9 has a smaller diameter than the first opening 8 because of a collar 36 at the top end of the melting zone, which is also the end of the water cooled segments 5 in the smelting cyclone.

The first opening 8 of the smelting cyclone is where a reducing process gas 10 enters the smelting cyclone. The partial combustion of the reducing process gas with the supplied oxygen generating the heat for melting the iron ore and the remaining part pre- reducing the iron ore. The resulting process gases 11 leave the smelting cyclone 1 through the second opening 9 which is connected to an exhaust system not further indicated in the drawing. The molten iron oxides 12 flow or drip along the water cooled segments 5 downward and drop from the last water cooled segment 5 into a container, such as a metallurgical vessel, where the final reduction of the iron oxides will take place. Depending on the connection between the smelting cyclone and a metallurgical vessel the molten iron oxides may also flow from the smelting cyclone along the roof of the vessel and drip down the wall into the molten bath. Against the water cooled segments 5 a layer of iron oxides will accumulate which at the side facing away from the segments 5 allows a temperature above the melting temperature of iron oxides.

The smelting cyclone 1 is connected to a cone shaped wall 13 which may be the support of the smelting cyclone with which it can be mounted on a metallurgical vessel or it may be part of a metallurgical vessel to which the smelting cyclone is fixed. The cone shaped wall 13 will also have to be cooled if it is mounted to or part of a metallurgical vessel.

Although heat is generated in the smelting cyclone and in the metallurgical vessel to which the smelting cyclone will normally be fixed, the temperature at the first opening 8 may get below the melting temperature of iron oxides. This may lead to solidification of the molten iron oxides and to accretions of solidified iron oxides.

Through the cone shaped wall 13 oxygen injectors 14 project. In the given example the oxygen injectors have a first part 15 which project at about a straight angle through the cone shaped wall 13 and a second part 16 at an angle to the first part 15. The oxygen injectors 14 are positioned such that the injected oxygen will contact the reducing process gas 10 in the region of the first opening 8 therewith preventing that the molten iron oxides can solidify at this point.

The oxygen injectors 14 are rotatable around the first part 15 thereof resulting in that the direction of the injected oxygen can be varied.

In fig. 2 a possible arrangement is indicated schematically. The oxygen injectors 14 are placed around and below the circumference of the first opening 8 of the smelting cyclone, which could be done with two opposite injectors, with three injectors at 120°, four injectors at 90° and so forth. For clarity's sake only two injectors 14 are shown in the drawing.

The oxygen injectors 14 can be rotated from a position where the oxygen is injected at an angle with respect to the first opening 8 of smelting cyclone 1 without a tangential component, as indicated with the broken line 17, to a position where the oxygen is injected in a more or less tangential direction with respect to the first opening 8 indicated with the position of the second part 16 of the injector.

A further example of an injector is indicated with 18 which comprises a straight part provided with a nozzle at or near an outer end of the injector which direct the oxygen leaving the injector at an angle. With the injector being rotatable it is possible to cover a wide area with the injected oxygen as indicated with the broken lines 19. It is of course also possible to have a nozzle at the outer end of injector 18 and injecting the oxygen only in tangential direction. Such an injector 18 does not need to be rotatable.

Preferably the injectors 14 or 18 are all oriented the same with respect to the circumference of the first opening 8 of the smelting cyclone 1, that is that all oxygen is directed to the centre of the first opening 8 or away from said centre, for example with a tangential component or only in tangential direction. Moreover, the tangential component or tangential direction of the oxygen injected by each of the oxygen injectors 14, 18 is preferably in line with the direction of rotation in the smelting cyclone 1.

Fig. 3 shows a diagram for the oxygen supply to the oxygen injectors 3 of the smelting cyclone 1 and the further oxygen injectors 14, 18. An oxygen supply with control system is schematically indicated with 20 which is connected to a common duct 21 for a first group 22 of injectors 3 and a second group 23 of injectors 14, 18. The injectors 3, 14, 18 of both groups 22, 23 are each provided with a valve 24 by means of which the ratio between the oxygen supplied to the smelting cyclone 1 and the oxygen supplied to the injectors 14, 18 below the smelting cyclone 1, as well as the total amount of oxygen supplied, can be adjusted and fine tuned. This is important because the ratio between the amount of pre-reducing gas needed to generate sufficient heat to melt the iron oxides and to prevent that the molten iron oxides could solidify again and the amount of reducing gas needed to pre-reduce the iron oxides has to stay within a certain range to be most effective. In fig. 4 another configuration for the oxygen supply system is shown wherein the oxygen supply with control system schematically indicated with 20 is connected to a duct 21 for the first group 22 of injectors 3 and to a duct 25 for the second group 23 of injectors 14, 18. In this configuration the injectors 3 of the first group 22 are each provided with a valve 24 and the injectors 14, 18 of the second group 23 now have in the duct a single adjustable valve 26 and a flow meter 27. This configuration with flow measurement allows for an easier adjustment for both groups 22, 23 of injectors.

Further configuration are possible such as a single valve and a flow meter also for the first group of injectors 3 or a single valve and a flow meter for every so many injectors of the first group of injectors 3.

In yet another configuration, separate oxygen supply system could be provided for each group 22, 23 of injectors with further control means to control the ratio and amount of oxygen supplied to each group 22, 23 of injectors.

Finally, separate oxygen supply systems could be provided for each individual injector in group 22 and 23.

Fig. 5 shows an apparatus 30 consisting of a smelting cyclone 1 coupled to a metallurgical vessel 29 for the production of molten iron. An oxygen supply with control system, schematically indicated with 20, supplies oxygen to the smelting cyclone via oxygen injectors 3, to the metallurgical vessel 29 via lances 28 and to oxygen injectors 14, which project through the roof 31 of metallurgical vessel 29 below the first opening 8 of the smelting cyclone 1.

The metallurgical vessel 29 is provided with a lining 32 of refractory material at the lower part of the vessel. In this lower part liquid metal 33 accumulates with on top thereof liquid slag 34 during operation of the apparatus. Further, lances 35 are provided to inject coal and additives in the liquid slag 34.

A configuration such as shown in fig. 5 allows for the injection of the total oxygen supplied to the apparatus distributed over oxygen injectors 3 in the smelting cyclone, the oxygen injectors 14 below the first opening 8 of the smelting cyclone and the lances 28, where the distribution is determined on basis of local heating requirements in the apparatus and/or requirements to the reduction potential of the process gas. Similar to the descriptions for fig 3. and fig. 4, the oxygen supply to the injectors 3, 14 and to lances 28 may be from a single oxygen supply with control system 20, such as indicated in fig. 5, properly configured with valves and flow meters so to achieve the desired distribution among the injectors and lances.

Another configuration (not displayed in fig. 5) foresees in having a dedicated oxygen supply with control system for the injectors 3 present in smelting cyclone 1 and for the injectors 14 at or near the first opening 8 of the smelting cyclone 1 and a dedicated oxygen supply with control system for the lances 28.

In yet another configuration (not displayed in fig. 5), dedicated oxygen supply systems with control system are installed for oxygen injectors 3, for oxygen injectors 14 and for lances 28.

In still another configuration (not displayed in fig. 5), dedicated oxygen supply systems with control system are installed for each individual injectors 3, 14 and lances 28.

Claims

1. Smelting cyclone for the production of pre-reduced molten iron oxides, wherein the smelting cyclone is provided with a first and second opening, the first opening serving as an inlet for reducing process gas and as an outlet for molten pre- reduced iron oxides and the second opening serving as an outlet for process gas, with supply means to supply iron ore into the smelting cyclone and with oxygen supply means to supply oxygen into the smelting cyclone, characterised in that additional heating means are provided to prevent solidification of molten iron oxides at or near the first opening of the smelting cyclone, wherein the additional heating means comprise one or more oxygen injectors that in operation inject oxygen from a location below the first opening of the smelting cyclone in a direction such that the injected oxygen will come into contact with process gas entering the first opening.

2. Smelting cyclone according to claim 1, wherein the one or more oxygen injectors are positioned outside the circumference of the first opening as seen in vertically downward direction.

3. Smelting cyclone according to claim 1 or 2, wherein the oxygen injectors are arranged such that in operation the oxygen is injected in a direction which is at least partially in line with the direction of flow of process gas entering the smelting cyclone.

4. Smelting cyclone according to one or more of claims 1-3, wherein the oxygen injectors are arranged such that in operation combustion of the injected oxygen and part of the process gas takes place in the region of the first opening of the smelting cyclone.

5. Smelting cyclone according to one or more of claims 1-4, wherein two or more oxygen injectors are spaced around the circumference of the first opening of the smelting cyclone.

6. Smelting cyclone according to claim 5, wherein the oxygen injectors are adjustable such that the direction of injection of the oxygen can be adjusted.

7. Smelting cyclone according to one or more of claims 1 -6, wherein the oxygen injectors are connected to the oxygen supply for the supply means to supply oxygen into the smelting cyclone.

8. Smelting cyclone according to claim 7, wherein the oxygen injectors and the supply means to supply oxygen into the smelting cyclone are separately adjustable.

9. Smelting cyclone according to claim 9, wherein the oxygen injectors are provided with common flow meter means and common adjusting means to adjust the total amount of injected oxygen.

10. Smelting cyclone according to one or more of claims 1-6, wherein the oxygen injectors are connected to an oxygen supply separate from the oxygen supply for the supply means to supply oxygen into the smelting cyclone.

1 1. Apparatus for the production of molten iron comprising a metallurgical vessel and a smelting cyclone according to one or more of the previous claims provided on the top part of the metallurgical vessel and in open connection with the interior of the metallurgical vessel, characterised in that the one or more oxygen injectors extend through the wall of the metallurgical vessel at a position below the first opening of the smelting cyclone.

12. Apparatus according to claim 1 1, wherein the oxygen injectors extend through the vessel wall spaced around the circumference of the first opening of the smelting cyclone.

13. Apparatus according to claim 11 or 12, wherein the metallurgical vessel has a bottom part with a refractory lining for accommodating a molten iron bath and a water cooled pressure resistant top part.

14. Apparatus according to claims 1 1-13, wherein the metallurgical vessel is provided with coal supply means and further oxygen supply means for the final reduction process of molten iron in the bottom part of the metallurgical vessel.

15. Apparatus according to claims 11-14, wherein oxygen supply means are provided for in at least three zones.