EP0166679A1 - Arrangement for a gasifier and direct reduction furnace - Google Patents

Abstract

In the case of an arrangement comprising a gasifier and a direct reduction shaft furnace positioned above it and which is connected to the gasifier by a connecting shaft, the direct introduction of the reduction gas obtained in the gasifier, even in the case of a high dust proportion, is made possible in that the sponge iron particles are discharged through several radially positioned screw conveyors and the reduction gas is fed to an annular zone formed above the screw conveyors.

Description

The invention relates to an arrangement according to the preamble of claim 1.

In the arrangement of this type which has become known from EP-A-1 _- 0094 707, the reducing gas is generated in a melting vessel in which oxygen and powdered coal are blown onto a liquid iron bath which serves as reaction medium and the ratio of CO and C0 _{2 influenced} in the gas produced. The reducing gas generated is fed directly into a direct reduction shaft furnace arranged above the melting vessel via a connecting shaft, in which it is cooled to the required reducing gas temperature by an injected coolant. This contains a bottom in the form of an inverted cone, through which the pouring column in the shaft furnace is supported. The wall of the shaft furnace is led outwards, forming an annular gap above the floor. The bottom layer of the sponge iron particles can be conveyed through the annular gap into the connecting shaft to the melting vessel by rotating a spiral-shaped slide in the center of the base. At the same time, the ascending reducing gas reaches the direct reduction shaft furnace via this annular gap.

The known arrangement assumes that the proportion of dust in the reducing gas introduced into the direct reduction shaft furnace via the connecting shaft is low. A reducing gas with a high dust content, for example a gas such as that obtained in a fluidized bed gasifier or in the melter gasifier described in DE-PS 28 43 303, would shortly result in the spaces in the lower column of the column being clogged by the dust carried along. In the case of a highly dust-laden gas, the amount of reducing gas supplied to the direct reduction shaft furnace directly via its discharge openings for the sponge iron had to be limited to approximately 30% of the total amount required for the reduction process (DE-PS 30 34 539).

The object of this invention is to provide an arrangement of the type mentioned in the preamble of claim 1 in such a way that a gas laden with a larger proportion of dust in the amount required for direct reduction directly from the gasifier to the direct reduction shaft furnace can be supplied without clogging of the interstices of the column by the entrained dust and as a result of this an uneven gas distribution in the direct reduction shaft furnace and malfunctions.

The object is solved by the features of claim 1. Advantageous embodiments of the invention can be found in the subclaims.

The measures according to the invention increase the cross section of the gas into the pouring column and thus reduce the gas velocity and the depth of penetration of the dust particles.

The constant increased movement of the sponge iron particles ensures the required gas permeability, especially in the penetration area of the reducing gas into the bed.

In the device claimed, an annular zone is created in the lower region of the pouring column, in which the iron sponge particles are kept in motion by a mechanical device which is particularly suitable for this purpose, and at the same time their rate of descent is increased. This zone extends from the foot of the pouring column over a larger area of the bed and thus creates the possibility of increasing the inlet cross section for the reducing gas into the bed and thus the flow rate for a given throughput of the gas introduced into the bed and, as a result, the depth of penetration of the dust particles. When using radially arranged screw conveyors located in the bed, the sponge iron particles are continuously and evenly distributed over the circumference and withdrawn from the ring zone and fed to the melter gasifier or to the outside. The sponge iron particles are preferably discharged from the direct reduction shaft furnace both outwardly via an annular gap or downpipes and also inwardly through a central opening in the bottom of the direct reduction shaft furnace. The conveying can be controlled in any direction by means of screw conveyors which can be driven in both directions of rotation. For example, all of the screw conveyors can alternately be conveyed outwards and then inwards in predetermined time periods, or a sector-specific conveyance can also be provided with the aim of keeping all sponge iron particles in motion in the ring zone and local clogging by means of the reducing gas to avoid entrained dust.

• Fig. 1 und 2 einen Längsschnitt und einen Querschnitt des für die Erläuterung der Erfindung wesentlichen Teils einer ersten Ausführungsform,
• Fig. 3 und 4 in analoger Darstellung eine zweite Ausführungsform, und
• Fig. 5 den Antrieb der Förderschnecken.

The invention is explained in more detail by two exemplary embodiments with reference to five figures. Each shows in a schematic representation:

• 1 and 2 show a longitudinal section and a cross section of the part of a first embodiment essential for the explanation of the invention,
• 3 and 4 in a similar representation, a second embodiment, and
• Fig. 5 the drive of the screw conveyor.

1 shows in a longitudinal section the upper part of a carburetor 1 and the lower part of a direct reduction shaft furnace 2 arranged above it. The direct reduction shaft furnace contains a base formed from a support structure 3 and a table top 4, by means of which the pouring column 5 can be supported in the shaft furnace. The upper part of the pouring column consists of lumpy iron ore or iron oxide pellets charged from above into the direct reduction shaft furnace and in the lower part of the sponge iron particles formed from it by direct reduction. The direct reduction shaft furnace is connected to the carburetor 1 by a connecting shaft 6.

The bottom formed by the support structure 3 and the table top 4 contains an annular gap 7 and a discharge opening designed as a central opening 8 for the sponge iron particles. In the area of the support structure 3, this annular gap is bridged at the points required for the attachment of the support structure. Both discharge openings are shielded from the pouring column 5, namely by an annular contactor 9 or a cone 10. The sponge iron particles are whirled through one another by a conveyor element formed from a plurality of radially arranged conveyor screws 11 and from the lower section of the The pouring column 5 is conveyed both to the annular gap 7 and to the central opening 8. For this purpose, the screw conveyors, as indicated by double arrows 12, can be driven in both directions of rotation by individually assigned drives 13. The radial arrangement of the screw conveyors can be seen in FIG. 2, which represents the section II-II of FIG. 1.

Thereafter, in the exemplary embodiment, eight conveyor screws 11 are provided which are distributed uniformly over the circumference.

Instead of the screw conveyors 11, any other mechanically acting devices for swirling and preferably also for transporting the sponge iron particles can also be used; for example a rotor, a thrust segment or another driver device or a vibration or vibrating device.

As shown in FIG. 1, the ring apron 9, which serves to shield the annular gap 7, and the cone insert 10, which serves to shield the central opening 8, end just above the conveyor element formed by the screw conveyors 11. With the formation of natural angles of repose below the edges of the shielding elements, the pouring column 5 is supported on the table top 4, which must be dimensioned taking into account these angles of repose. An annular space 14 is formed behind the ring apron 9 and above the natural pouring angle of the bed, via which reducing gas is introduced into the pouring column.

In the case shown in FIG. 1, the interior of the direct reduction shaft furnace extends downward outside the upper end of the ring apron and the inside of the ring apron is flush with the inside of the wall section of the direct reduction shaft furnace 2 above. The wall of the direct reduction shaft furnace could also be without extension in the area of the floor be trained if the ring apron is guided conically inwards.

It is advantageous that the passage cross-section for the sponge iron particles in the area adjacent above the conveying member is shaped into an annular zone 15, to which the hot reducing gas can be fed from the carburetor 1 evenly distributed over the circumference. In the present case, this ring zone 15 is formed only by the cone insert 10 and the hot reducing gas is, as indicated by arrows 16 and 17, introduced through the annular gas inlet areas 18 and 19 evenly distributed over the circumference into the bulkhead 5. As a result, the hot dust-laden reducing gas reaches a region of the pouring column 5 over a large inlet cross-section, in which the sponge iron particles are kept in constant motion by the screw conveyors 11 and are conveyed at an increased throughput speed compared to higher-lying zones. In this way, as has already been explained above, even with a heavily dust-laden gas, the risk of local clogging of the interstices in the bulkhead can be further reduced and uniform through-gassing of the direct reduction shaft furnace can be achieved.

This effect can be favored if the screw conveyors are designed in the form of an interrupted screw path formed by paddling, as they have become known from DE-PS 30 34 539, and if the screw conveyors can be driven individually in both directions of rotation, as in the present case.

In the embodiment shown in FIG. 1, the sponge iron particles discharged via the annular gap 7 are fed through the connecting shaft 6 to the carburetor 1, which is designed as a melter gasifier, and the sponge iron particles discharged via the central opening 8 through a discharge pipe 20 via a nozzle 21 to the outside headed. Modified constructions can of course also convey all iron sponge particles to the outside or into the carburetor 1 or, if necessary, make any division of the partial streams.

In order to reduce the temperature are the recovered in the gasifier 1-temperature reducing gas to the required for the direct reduction shaft furnace temperature at the Ausführun ^g sbei- game of FIG. 1 also indirect cooling through a heat exchanger 22 and a direct cooling by admixing cooling gas through a central cooling gas distributor 23 provided. The cooling gas is a reducing gas drawn off through a nozzle 24, which is cooled in a cooling gas scrubber 25 and then fed to the cooling casedistributor 23.

The reducing gas generated in the carburetor 1 passes through the connecting shaft 6, in which it is set to the required temperature, through the annular gap 7 or the central opening 8 into the annular space 14 or the space below the cone insert 10 and from there through the annular ones Gas inlet areas 18 and 19 into the pouring column.

As shown in FIG. 2, the sponge iron ^p articles 5 can be continuously conveyed to the outside the annular gap 7 or inwards towards the central opening 8 through the distributed over the circumference arranged screw conveyor 11 from the lowermost portion of the discharge column. In order to avoid dead zones, the screw conveyors can be designed to taper inwards towards the central opening 8 (not shown), or, as indicated by dash-dotted lines, wedges 26 can be arranged between adjacent screw conveyors, both towards the central opening 8 as well as converging upwards.

In the second exemplary embodiment according to FIGS. 3 to 5, the same reference numbers are used for parts which correspond to those of the first exemplary embodiment according to FIGS. 1 and 2. The second embodiment differs from the first one essentially in that the direct reduction shaft furnace 2 arranged above the carburetor is supported on its own supporting frame 31. The bottom 32 of the direct reduction shaft furnace supporting the pouring column 5 has only one central opening 8 as a discharge opening for the sponge iron particles, so that the floor can be supported without cooling problems. Downpipes 33 can also be provided, of which one is shown in broken lines, which make it possible to convey the sponge iron into the carburetor 1 from the outer end of the screw conveyors. For this purpose, stubs 34 are provided in each case in the outer region of the conveyor screws and these are each connected to the interior of the carburetor 1 by a down pipe 33. In this case, of course, the screw conveyors can also be driven in both directions of rotation, or a combination of screws conveying outwards and conveying inwards can be provided.

In the second exemplary embodiment, too, most of the reducing gas is blown into the annular zone 15 from the periphery via an annular inlet. This part is designated by a. Since, by eliminating the annular gap 7 of the first embodiment, the reducing gas can no longer be passed via this path into the annular space 14 formed behind the annular skirt 9, at least one connecting piece 35 opening into the annular space 14 is provided, which has a gas line 36 with a gas outlet 37 of the carburetor 1 is connected.

In the second exemplary embodiment, the cone insert 10 has passage openings 38 into which the inner ends of the radially arranged screw conveyors 11 engage. These passage openings 38 form a gas inlet for the reducing gas rising in the carburettor shaft 6, specifically for the partial flow denoted by b. Another partial flow c is introduced into the annular zone 15 through an annular gap 39 of the cone insert 10. In addition, in the case of existing down pipes 33, a partial flow passes through these into the pouring column. The partial flow a forms approximately 65 volume percent, the partial flow b forms approximately 25 volume percent, and the partial flow c forms approximately 10 volume percent of the hot reducing gas introduced into the ring zone 15. Since the gas is introduced over a large cross-section, there is a low speed and a low penetration depth of entrained dust particles, so that the risk of clogging of the spaces between the sponge iron pellets is further reduced even with a reducing gas with a high dust content, and an even gas distribution can be ensured . In the connecting shaft 6 and in the gas pipe 36, nozzles 40 are provided for introducing cooling gas. In addition, the connecting shaft contains a compensation section 41, by means of which height differences from the floor 32 supported by the frame 31 can be compensated.

The drive 13 shown in FIGS. 3 and 5 is designed in the form of a ratchet mechanism, with each feed screw 11 being assigned two such drives if the feed screw is to be drivable in both directions of rotation.

Claims (17)

1. Arrangement of a gasifier, in particular a melter gasifier and a direct reduction shaft furnace with a bed of lumpy iron ore or iron oxide pellets, the bottom, through which the column in the shaft furnace can be supported, at least one discharge opening in the bottom for the discharge of the sponge iron particles and at least one preferably contains an annular inlet for the reducing gas supplied by the carburetor into the bed in the lower section of the pouring column, characterized in that a mechanical device for constant mutual movement of the particles of the bed in the area adjacent to the inlet for the reducing gas and through which the reducing gas flows, at least during its supply is provided. 2. Arrangement according to claim 1, characterized in that the reducing gas can be fed evenly distributed over the circumference of the furnace (2). 3. Arrangement according to claim 2, characterized in that the passage cross section for the sponge iron particles above the bottom (3, 4; 32) is reduced by an insert (10) to an annular zone (15) to which the reducing gas can be supplied. 4. Arrangement according to one of claims 1 to 3, characterized in that the lower end of the furnace (2) is connected by a connecting shaft (6) to the carburetor (1). 5. Arrangement according to one of claims 1 to 4, characterized in that the mechanical device is simultaneously provided as a conveying member for conveying the sponge iron particles to the discharge opening (7,8; 34). 6. Arrangement according to claim 5, characterized in that the mechanical device is formed by a plurality of radially arranged screw conveyors (11). 7. Arrangement according to one of claims 1 to 5, characterized in that the mechanical device is formed by a rotor, a thrust segment or another driver device. 8. Arrangement according to one of claims 1 to 5, characterized in that the mechanical device is formed by a vibration or R ttelvorrichtung. 9. An arrangement according to claim 6, characterized in that the conveyor screw (11) ^g in the form of an interrupted screw formed by paddles are formed angs. 10. Arrangement according to claim 6 or 9, characterized in that wedges (26) are arranged in the circumferential direction between the screw conveyors (11). 11. Arrangement according to one of claims 1 to 10, characterized in that a discharge opening for the sponge iron particles is provided as an annular gap (7) between the bottom (3, 4) and the inner wall of the direct reduction shaft furnace (2). - 12. Arrangement according to one of claims 1 to 11, characterized in that a discharge opening for the sponge iron particles is provided as a central opening (8) in the bottom (3, 4; 38) of the direct reduction shaft furnace (2). 13. Arrangement according to one of claims 1 to 12, characterized in that the wall of the direct reduction shaft furnace (2) has an annular apron (9) and an annular space (14) forming behind the annular apron (9) above the natural angle of repose of the fill with a Gas outlet (6,37) of the carburetor (1) is connected. 14. Arrangement according to claim 13, characterized in that the interior of the direct reduction shaft furnace (2) outside of the upper end of the ring skirt (9) extends downward and the inside of the ring skirt (9) with the inside of the overlying wall section of the direct reduction shaft furnace (2) flees. 15. Arrangement according to one of claims 3 to 14, characterized in that the Ke ^g el insert (10) forms at least one shielded from the bed, connected to the carburetor, annular gas inlet (19, 39). 16. Arrangement according to one of claims 6 and 9 to 15, characterized in that the inner ends of the radially arranged screw conveyors (11) engage in through openings (38) of the cone insert (10) which a gas inlet connected to the carburetor (1) for form the reducing gas. 17. Arrangement according to one of claims 6 and 9 to 16, characterized in that the outer ends of the radially arranged screw conveyors (11) are each assigned a discharge opening (34) for the sponge iron particles connected to the carburetor (1) by a connecting line (33) is.

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