EP0004373A2 - Method and apparatus for operating an iron producing blast furnace - Google Patents

Abstract

Blast furnaces for reducing iron ores show pronounced subsidence of coke and ore layers in an annular zone above the tuyère hollows, while the subsidence in the central and edge zones is minimal. In contrast, the gases rise preferentially through the central and edge zones. Their specific quantity is much increased in these zones, but much lower within the annular zone. This retards the reduction in the annular zone, which consequently takes place to any extent only near the tuyère level, necessitating an increased coke and air consumption. By charging the central and edge zones with coke and ore of smaller particle size compared with the annular zone and with a coke input of from 100 to 200 kg per t of crude iron the flow of the gases and the reduction are substantially balanced out in the 3 zones. The result is a coke saving of 5-10% and a corresponding saving in air, amounting to increased productivity.

Description

Blast furnaces for the reduction of _E isenerzen in the form of lump ore, sinter, pellets or the like. Are fed usual such that the ore is with and without additional batch abandoned separated from the coke. The procedure is such that the batch of gout bells closes more or less strongly against a cylinder with adjustable diameter as an impact armor and is more or less pushed back from there or practically falls vertically downwards. The material hits the fill in a ring, rolls to the center and to the edge and forms an embankment to the center and to the edge with a slope of normal 30 - 35 ⁰ . This is the usual practice, since in the ring zone a stronger decrease in the bed than is done in the middle, and thereby the stratification after a certain drop in ^p RAK table is horizontal.

The embankment on the one hand to the center and on the other hand to the edge of the shaft causes the coarse material to roll preferentially to the center and to the edge in both the ore and coke batches and promote the flow there. This corresponds to the prevailing practice that one is somewhat stronger on the edge and in the middle, but otherwise completely even gas flow provides the best operating results. A completely even distribution of coke and ore is also sought over the entire cross-section of the shaft.

In recent times, a rotating chute is preferred as the feed device, the angle of inclination of which can be changed depending on the feed of coke or ore, so that the material can hit the bed in a narrower or wider ring, e.g. is described in German patent specification 2320 532. However, nothing fundamental has been changed in the way coke and ore are distributed across the shaft cross-section.

It is known that the blown air blown on the blow molds with and without the addition of fuel and / or oxygen in the individual blow mold cavities burns at a penetration depth of up to approximately 1.5 m of coke and the CO ₂ generated and the air humidity in the coke bed to CO and H _{2 are} implemented. For this, 70 - 75% of the total coke + fuel used is usually consumed, while about 5 - 8% is required for the carburization of the iron and about 20 - 24% for converting the CO ₂ on the coke formed by the reduction of the ore to 2 CO become. The heavy consumption of approximately 70-75% of the total coke in the blow mold cavities, each with an active length of 1.5-2.0 m and a diameter of approximately 0.8 m, causes coke to sink sharply into these cavities, whereby the coke layers take the ore layers accordingly. Thus, in a ring zone, which is formed at the bottom by the blow mold cavities and widens radially upwards, the coke and ore layers sink to a highly preferred extent, while in the blow mold plane outside the blow mold cavities only very little Coke is consumed and therefore no ore layers sink there.

The mold gases formed from CO + H _{2 in} addition to N ₂ in the blow mold cavities are distributed from the blow mold cavities over the entire shaft cross-section, with the flow being considerably increased towards the center and partly also at the edge and between the blow mold cavities, since there layers predominantly or exclusively from lumpy coke, which participates only to a very small extent in the reactions, while above the blow mold cavities alternately coke and partially reduced ore layers occur, which offer greater flow resistance. In the ring zone above the blow mold cavities, coke and ore layers sinking rapidly downward meet specifically smaller amounts of mold and shaft gases. Specifically, significantly smaller amounts of heat and CO + H _{2 are available} for the reduction in the ring zone than in the central and peripheral zone. Inevitably, the reduction above the blow mold cavities cannot be completed and the iron ore enters the blow mold cavities only partially reduced and unmelted. This leads to the reduction and melting of iron and slag in the blow mold level, which results in higher C consumption and air consumption.

The situation in the middle and marginal area is different. There, a specifically high amount of molding gases initially only comes into contact with coke and already molten, dripping, reduced iron, along with dripping molten slag, and only in higher shaft zones with ores that have not yet been reduced and melted. Only then is coke consumed by converting the oiled GO ₂ on the coke to 2 GO. The sinking of the coke in the The middle of the shaft is inevitably very low due to the small consumption and is only stronger where coke layers sink into the "throat" above the blow mold cavities. The coke fill in the middle zone heats up accordingly, the rising gases cool only slowly and only more strongly in the upper zones.

The reduction and melting zone located high in the middle zone leads to an early consumption of the ore layer, so that underneath there are only layers of coke with considerably lower flow resistance, in which coke is only used to carburize the iron. These phenomena are the reason for the formation of the "dead man" in the form of a cone in the middle of the shaft, which is not so "dead" at all. In it there is an increased gas flow compared to the ring zone, whereby the CO is used less. Since the cone becomes more pointed at the top, the shaft gases that rise in it have to dodge to the side so that larger cross currents and mixing can occur.

There are therefore large differences between the middle and edge zones compared to the ring zone with regard to gas flow, heat and CO utilization, the reduction and melting of the iron and slag. Overall, these differences inevitably lead to a specifically higher coke consumption, to a specifically higher amount of wind and thus to a reduced output.

German patent specification 1 758 372 claims a method of adding fuel in the middle and a ring zone on the wall and Möller in the ring zone in between. For this purpose, ring-shaped partitions and a discharge of top gases from two zones are recommended in the upper part.

German patent specification 1 252 214 claims a method of heating coke with a grain size of 5-50 mm in an amount of about 400 kg / t of pig iron in the peripheral zone and next to it in the middle zone Möller and reduction and coaling coke with a grain size of 50-80 mm give up in an amount of about 200 kg / t RE.

The aim of the invention is to largely compensate for the differences between the individual zones. A certain compensation is achieved by the known injection of fuel through the blow molds, whereby coke is saved and the sinking of the bed in the ring zone is slowed down. According to the invention, measures are carried out to increase the flow resistance in the middle and edge zone and to reduce it in the ring zone. Furthermore, above average ore and therefore below average coke should be added to the middle and peripheral zone in order to better utilize the heat and CO of the shaft gases rising there. In the middle zone, only coke for the conversion of C0 ₂ to 2 C0 and for carburizing the iron in an amount of 100 to 200 kg C / t of the pig iron produced there can be used. Correspondingly, ore is to be supplied in an increased quantity to the central zone and similarly to the peripheral zone, it also being possible here to use the finer ore with greater flow resistance. The coke should also preferably be smaller than it is fed to the ring zone. For this purpose, the coke available to the blast furnace is expediently separated into two grain classes, namely with a grain size of, for example, above 50 and below 50 mm.

With the usual bell lock, a center drop can be achieved in that the bell additionally has a central outlet with its own bell lock or better with lower flap lock with connected central downpipe. The bell is then operated as usual to charge ore and coke. In addition, with the bell closed, the desired quantity of ore is fed through the central zone in the middle zone. By appropriate training of the bell and the adjustable impact armor and the appropriate actuation of both organs in conjunction with the appropriate depth, it can be ensured that ore, possibly fine-grained type, and / or coke of fine-grained type are supplied to the peripheral zone.

Additional quantities of ore in the middle and in the edge zone are expediently introduced to the extent that an advance in the temperatures in the middle and edge zones is observed in relation to the ring zone and how the coke consumption is optimally reduced. The central and peripheral zone of coke is expediently fed in in an amount of only 100-200 kg t of pig iron and preferably in small pieces, while the ring zone is supplied with as much coke and preferably in a coarse manner as the blast furnace as a whole requires.

If a flap lock with a central downpipe and a rotating chute is available instead of a bell lock with impact armor, the angle of inclination of the coarse or fine material of coke or ore can be changed depending on the task, e.g. described in German patent specification 2320 532 so that the impact point for the material in the middle, ring and edge zone can be set as desired, so the measures according to the invention can be implemented with simple means.

If a rotating chute is available, it is also possible to reinforce the ore and fine-grained edge zone Add coke between two blow molds. Between the blow molds the lowering of the fill is less than directly above the blow molds, so that it can be blown through more easily here. This can be prevented if the rotary chute is stopped in the middle between two blow molds for a certain time when adding ore or fine-grained coke to the edge zone. This measure can be carried out in regular periods or also when required, i.e. in the case of observed marginal disorders.

If the flow of the shaft gases is improved in favor of the ring zone and if the ore instead of coke is added to the central and peripheral zones, more shaft gases will be available to the ring zone and at the same time it will be relieved of part of the reduction work. The heating of the ore and the reduction of the ore can already take place in a higher shaft zone at lower temperatures. The reduction and possibly also the melting of iron and slag can thus be completed before the blow mold level and the heat-consuming C0 ₂ cleavage on the coke can be better suppressed. These improvements to the shaft work reduce the heat requirement on the mold level, the required specific air volume and coke consumption, and increase the performance of the blast furnace with a constant wind volume by at least 5% for already well-managed and also about 15% for previously poorly managed blast furnaces.

Claims (7)

1. A method of operating a blast furnace for the reduction of iron ores in the form of lump ore, sinter, pellets or the like., Characterized in that the flow resistance in the central and peripheral zone of the shaft against the ring zone is increased, and / or that the middle - and the marginal zone specifically abandon more ore and less coke than the ring zone. 2. The method according to claim 1, characterized in that the central and peripheral zone of the shaft is preferably fed to the more fine-grained ore. 3. The method according to claim 1 + 2, characterized in that the center and edge zone of the shaft is preferably fed to the finer-grained coke. 4. Apparatus for carrying out the method according to claims 1-3, characterized in that the feed device for ore and coke is designed such that, depending on the batch of coarse-grained or finer ore or coke, it preferably throws off into the central zone, the ring zone or the peripheral zone . 5. The device according to claim 4, characterized in that the bell is additionally equipped with a central outlet in a bell closure of the gout. 6. The device according to claim 5, characterized by a central outlet with a lower flap closure and connected central downpipe. 7. The device according to claim 4, characterized by a charging device with central discharge of coke and ore in separate batches on a rotary chute with a controllable angle of inclination.