JPH01294811A - Method and apparatus for iron manufacturing - Google Patents

Abstract

PURPOSE:To improve heat efficiency and to reduce cost of equipment by forming coke packed layer and fluidized bed of powdery ore at upper part of the above packed layer in a furnace body and blowing oxygen and circulating gas from the lower part of the furnace body. CONSTITUTION:Lump coke is charged is the lower part of the furnace body 1 from a coke charging hole 3 to form the coke packed layer 9 and on the upper part of the packed layer 9 powdery ore is charged from a raw material charging hole 4 to form the fluidized bed 10 of the powdery ore. The oxygen is blown into the furnace body 1 through oxygen supplying pipe 11 connected with lower tuyeres 6. Further, circulating gas supplying pipe 17 for returning the circulating gas into the furnace body 1 from a cyclon 13, is connected with upper tuyeres 5. Therefore, as smelting reduction is executed at the lower part of the furnace body 1 and also preceeded it, pre-reduction is executed at the upper part of the furnace body 1 and sensible heat of gas at the time of executing the smelting reduction can be used as heat needed to the pre-reduction, and heat loss is a little and the excellent heat efficiency can de obtd.

Description

[Detailed Description of the Invention] "Field of Industrial Application" This invention relates to a new iron manufacturing technology that replaces the blast furnace method, and in particular,
The present invention relates to an iron manufacturing method in which fine ore is preliminarily reduced and then melted down, and to an iron manufacturing apparatus used to carry out the method.

``Conventional technology'' In recent years, proposals for new iron-making methods to replace the traditional blast furnace method have been made, and a typical method is to pre-reduce iron ore and then melt-reduce it to obtain pig iron. For example, those shown in FIGS. 2 and 3 have been proposed.

What is shown in FIG. 2 is a steel manufacturing equipment equipped with a shaft-type pre-reducing furnace a and a melter-gasifier placed below the shaft-type pre-reducing furnace a, in which raw ore is charged into the pre-reducing furnace a, A part of the furnace gas from the melter-gasifier is introduced into the furnace for preliminary reduction, and the pre-reduced raw material ore is fed into the melter-gasifier and melted and reduced there. It is. In this case, lump ore or pellet shaped ore is used as the raw material ore, and steam coal is used as the reducing agent.

In Fig. 2, C is a fan for circulating the gas in the furnace and feeding it into the melter-gasifier, d is a gas cooler for cooling the circulating gas, and e and f are for collecting dust in the circulating gas. The circulating gas blown into the melter-gasifier is returned to the gas cooler d via cyclones e and f, and a part of it is blown into the pre-reduction furnace a from the cyclone e. Re,
It is designed to be discharged through a scrubber g.

Moreover, what is shown in FIG. 3 is a steel manufacturing equipment equipped with a fluidized bed type pre-reduction furnace and a smelting reduction furnace i, in which fine ore is charged into the pre-reduction furnace, and then the smelting reduction furnace The ore powder is pre-reduced by introducing gas into the furnace from i to form a bubbling fluidized bed, and the pre-reduced ore powder is blown into the smelting reduction furnace i for melting and reduction.

The smelting reduction furnace i in this device has two upper and lower stages of tuyeres j, j.
, and hot air, oxygen, and pre-reduced fine ore are blown into the tuyeres j, j. In addition, a packed bed k of coal is formed in the lower part of the furnace of the smelting reduction furnace i, and a fluidized bed 1 of coal is formed above it, and the coal charged from the top of the furnace is It is heated in the fluidized bed 1 and descends to the lower part of the furnace to form a packed bed k.

"Problem to be Solved by the Invention" By the way, in the above-mentioned devices that have been proposed to date, the furnace for performing preliminary reduction and the furnace for performing smelting reduction are each separate. Therefore, various equipment is required to connect them process-wise, which makes the structure complicated, increases the equipment cost, and also complicates the operation.Furthermore, heat loss increases. However, it has problems in terms of efficiency and cannot be said to be fully effective.

In addition, the type shown in Figure 2 requires additional equipment such as a sintering machine to form the raw material ore into a pellet shape, and the type shown in Figure 3 requires a preliminary reduction furnace. There was also the problem that preliminary reduction in the process could not always be carried out sufficiently.

The object of the present invention is to provide an effective iron manufacturing method capable of solving the problems described in E, and an apparatus suitable for carrying out the method.

"Means for Solving the Problems" The iron manufacturing method of the present invention forms a coke-filled bed in a furnace body, and forms a fluidized bed of fine ore on top of the coke-filled bed, so that oxygen and circulation are carried out from the bottom of the furnace body. Preliminary reduction is performed by circulating the fine ore between a cyclone installed in parallel to the furnace main body by blowing gas, and the pre-reduced fine ore is guided from the cyclone to the coke packed bed where it is melted and reduced. It is characterized by this.

Further, the iron making equipment of the present invention has a tuyere at the bottom for blowing oxygen and circulating gas, and a circulating gas outlet at the top, and has a coke-filled bed inside and a fluidized bed of fine ore above it. A shaft-shaped furnace body is formed, and the furnace body is arranged in parallel with the furnace body and connected to the discharge port at the top of the furnace body, and the fine ore led from the furnace body together with the circulating gas is separated from the circulating gas and collected. a separator that separates the fine ore collected by the cyclone into pre-reduced ore that has been pre-reduced and unreduced ore that has not yet pre-reduced; and a separator that separates the circulating gas exhausted from the cyclone. and a circulating gas pressure feeding means for blowing into the furnace main body from the tuyere,
The unreduced ore separated by the separator is returned above the fluidized bed to circulate the unreduced ore between the furnace main body and the cyclone, and the pre-reduced ore separated by the separator is passed through the tuyeres together with oxygen. It is characterized by being configured to be blown into a coke packed bed.

In the above steelmaking equipment, an upper tuyere and a lower tuyere are provided at the lower part of the furnace body, and the pre-reduced ore separated by the separator is blown into the coke packed bed together with oxygen from the lower tuyere, and the circulating gas and It is desirable that the furnace be constructed such that oxygen is blown into the furnace body from the upper tuyere, and that the amount of oxygen blown from the upper tuyere and the lower tuyere can be adjusted respectively.

"Operation" In the present invention, raw ore powder is smelted and reduced in the lower part of the furnace body, but prior to that, it is preliminarily reduced in the upper part of the furnace body. That is, a fluidized bed of fine ore formed above the coke packed bed is blown up by circulating gas and guided to the cyclone, and while the fine ore is circulated between the furnace body and the cyclone, it is preliminarily reduced in the upper part of the furnace body. The pre-reduced ore powder is then guided from the cyclone to a coke-filled bed at the bottom of the furnace body, where it is melted and reduced.

"Example" An embodiment of the present invention will be described below with reference to FIG.

FIG. 1 shows the overall schematic structure of a steel making apparatus according to an embodiment of the present invention, and reference numeral 1 in the figure represents a furnace body.

This furnace body 1 is of a shaft type, and has a circulating gas discharge port 2 at the top, a coke charging port 3 at the top, a raw material charging port 4 for charging fine ore, and an upper tuyere 5 at the bottom. , and a lower tuyere 6 are provided, respectively. Further, at the lower end, a molten metal pool 7 and a tap hole 8 for taking out the hot metal accumulated therein are provided.

A coke-filled bed 9 is placed in the lower part of the furnace body 1 by charging lump coke from the coke charging port 3.
is formed, and the coke filled layer 9
A fluidized bed 10 of fine ore is formed in the upper part of the container by charging fine ore from a raw material charging port 4 . Further, an oxygen supply pipe 11 is connected to the lower tuyere 6, and this oxygen supply pipe 11 is connected to an oxygen supply source (not shown).
Oxygen at room temperature or high temperature is blown into the furnace body l through the furnace. Furthermore, a circulating gas supply pipe 17 for returning circulating gas from a cyclone 13 to the furnace main body 1 is connected to the upper tuyere 5.

Cyclones 13 are arranged side by side on the side of the furnace body l.

This cyclone 13 is connected to the discharge port 2 at the top of the furnace main body 1 via a riser (rising pipe) 14, and the furnace main body l
The fine ore is introduced together with the circulating gas, and the guided fine ore is separated and collected from the circulating gas and discharged from the lower end, and the circulating gas is exhausted from the upper part.

The fine ore collected by the cyclone 13 is sent to a separator 15, where it is sorted and separated into pre-reduced ore that has been pre-reduced and unreduced ore that has not yet been pre-reduced. . This separator 15 is a so-called magnetic separator that uses magnetic force, and fine ore that has been sufficiently pre-reduced has magnetic properties.
Since fine ore that has not been sufficiently pre-reduced does not have magnetism, those that are attracted to a magnet are treated as pre-reduced ores, and those that are not adsorbed to a magnet are separated as unreduced ores. The unreduced ore separated by the separator 15 is returned upward to the fluidized bed 10 in the furnace body l through the return pipe 16, and the pre-reduced ore is sent to the oxygen supply pipe II and sent to the lower part with oxygen. Tuyere 6
It is designed so that it is blown into the furnace body l.

On the other hand, part of the circulating gas exhausted from the upper part of the cyclone 13 is returned to the furnace body 1 from the upper tuyere 5 through the circulating gas pipe 17. , a pressure booster 18 (circulating gas pressurizing means) for pressurizing and pumping the circulating gas is provided. Note that the remaining gas exhausted from the cyclone 13 is sent to a gas holder (not shown) for use as fuel.

In addition, a part of oxygen is sent to the booster 18 from the oxygen supply pipe [l, and the oxygen sent to the booster 18 is sent from the upper tuyere 5 into the furnace main body l along with the circulating gas. It is becoming more and more blown away. The amount of oxygen supplied into the furnace body 1 from the lower tuyere 6 through the oxygen supply pipe 11, and the booster! 8. From the upper tuyere 5 to the furnace body via the circulating gas pipe 17! The amount of oxygen supplied within each case can be adjusted by means of valves 19,20.

The configuration of the iron manufacturing apparatus of this embodiment has been explained above, and next, the iron manufacturing method using the above apparatus will be explained.

First, from coke charging port 3 to the furnace main body! A coke filled bed 9 is formed by charging lump coke into the coke.

At this time, as shown in Fig. 1, the peripheral part of the coke packed bed 9 is made to be slightly higher than the central part, and the central part is filled with relatively large coke and the peripheral part is filled with comparatively large coke. It is preferable to fill the coke with a small diameter so that the ventilation resistance at the center of the coke-filled bed 9 is smaller than that at the periphery.

Next, fine ore is charged from the raw material charging port 4 to form a fluidized bed IO of fine ore above the coke packed bed 9.

At that time, it is a good idea to mix powdered coal with powdered ore.

Then, the booster 18 is operated to supply the circulating gas to the upper tuyere 5.
The amount of circulating gas is blown into the furnace body 1, and the amount of the circulating gas depends on the cross-sectional area of the furnace body 1, the ventilation resistance of the coke packed bed 9, the particle size of the fine ore forming the fluidized bed IO and the powder coal mixed therein, etc. Taking into account the following, the wind velocity of the circulating gas in the furnace body i should be greater than the particle terminal velocity of the fine ore and powdered coal, that is, the fine ore and powder should be fluidized by the circulating gas and blown upward. decide. At the same time, oxygen is blown in from the lower tuyere 6 and a part of it is blown in from the upper tuyere 5 via the booster 18.

As a result, the coke is combusted by the injected oxygen, and the circulating gas rises in the coke packed bed 9, and the fine ore at the top of the coke packed bed 9 is blown upward and flows into the cyclone 13 together with the circulating gas. be guided. At this time, the powdered coal mixed with the powdered ore is gasified and
The atmosphere inside the furnace body 1 is kept reducing by the reducing gas generated by the combustion of coke, so while the fine ore is rising inside the furnace body 1, the fine ore is reduced (in reserve) under that atmosphere. (refund) will be given.

The fine ore collected by the cyclone 13 is divided into those that have already been sufficiently pre-reduced and have magnetism (pre-reduced ore) and those that have not yet been sufficiently pre-reduced and therefore do not have magnetism (unreduced ore). (reduced ore) are separated by a separator 15. The separated unreduced ore is returned to the pipe 16.
The ore is returned to the furnace body 1 through the cyclone 13 and further reduced (preliminary reduction), thereby circulating between the furnace body 1 and the cyclone 13 until it is sufficiently reduced and becomes a preliminary reduced ore. On the other hand, the pre-reduced ore separated by the separator 15 is sent to the oxygen supply pipe 11 and is sent together with oxygen from the lower tuyere 6 into the coke packed bed 9, where it is melted and reduced to become pig iron and sent to the hot water pool 7. Accumulate.

In addition, a part of the circulating gas exhausted from the cyclone 13 is pressurized by the booster 18 and sent under pressure to the furnace body 1 through the upper tuyere 5, and is circulated between the furnace body 1 and the cyclone 13. .

According to the above method, melting reduction is performed in the lower part of the furnace body 1, and preliminary reduction is performed in the lower part of the furnace body 1.
Since the reduction is carried out in the upper part of the reactor, the sensible heat of the gas during the melting reduction can be directly used as the heat required for the preliminary reduction. Therefore, heat loss is small and excellent thermal efficiency can be obtained.

In addition, since melting reduction and preliminary reduction can be carried out using only one furnace body, equipment costs can be reduced compared to the case where they are each carried out in separate furnaces, and the operation is easy. .

According to this method, it is possible to use a wide range of particle sizes from relatively large to small particle sizes as the raw material powder ore, and any particle size is sufficient. can be redeemed in advance. That is, fine ore with a relatively small particle size is quickly pre-reduced before being led to the cyclone 13, and fine ore with a relatively large particle size and difficult to reduce is transferred between the furnace body 1 and the cyclone 1.
(The circulation time required for pre-reduction in that case is determined by the particle size, and the larger the particle size, the longer the circulation time.) If there is fine ore which is larger and cannot be blown up by the circulating gas, it will gradually descend within the coke packed bed 9, during which time it will be pre-reduced.

Furthermore, according to this method, the height of the coke packed bed 9 can be sufficiently lower than in the conventional blast furnace method, and therefore, there is less risk of crushing, so it is possible to use low-grade coke. .

Furthermore, by blowing in oxygen from both the lower tuyere 6 and the upper tuyere 5 and adjusting the amount of oxygen blown in from each with the valves 19 and 20, the internal temperature of the furnace body l can be maintained at a sufficiently high temperature. , it becomes easy to control optimally.

Incidentally, in the above embodiment, powdered coal was mixed into the raw material powdered ore, but if the reducing property in the furnace body can be sufficiently maintained by the gas generated from the coke,
There is no need to use powdered charcoal.

In addition, in the above embodiment, the tuyeres were provided in two stages, upper and lower, in the lower part of the furnace main body, but this is not necessarily the case. The pre-reduced ore may be blown into one tuyere (the upper tuyere 5 in the above embodiment).

"Effects of the Invention" As explained in detail above, the present invention forms a coke-filled bed in the furnace body, and forms a fluidized bed of fine ore on top of the coke-filled bed, thereby discharging oxygen from the bottom of the furnace body. The ore powder is pre-reduced while being circulated between the cyclones installed in parallel to the furnace main body by blowing circulating gas, and the pre-reduced ore powder is guided from the cyclone to the coke packed bed where it is melted and reduced. Because of this, it is possible to perform both preliminary reduction and melting reduction within one furnace body, which makes it possible to obtain excellent thermal efficiency, reduce equipment costs, and facilitate operation. In addition, it is possible to use a wide range of grain sizes as the raw ore powder, and it is also possible to use low-grade coke, which is an excellent effect.

In addition, by providing an upper tuyere and a lower tuyere at the bottom of the furnace body and adjusting the amount of oxygen blown in from each tuyere, the internal temperature of the furnace body can be maintained at a sufficiently high temperature and optimally controlled. This has the effect of making it easier.

[Brief explanation of the drawing]

FIG. 1 is an overall schematic diagram of a steel manufacturing apparatus according to an embodiment of the present invention. FIG. 2 and FIG. 3 are diagrams each showing a schematic configuration of iron manufacturing equipment that has been proposed up to now. 1...furnace body, 2...discharge port, 5...
...Upper tuyere, 6...Lower tuyere, 9...
... Coke packed bed, 10 ... Fluidized bed, 13.
...Cyclone, 15 ...Separator, 1
8... Booster (circulating gas pressure feeding means), 19.2
0... Valve. Figure 2 Figure 3 66-

Claims (3)

[Claims] (1) A method for producing pig iron by pre-reducing fine ore and then melting it down, in which a coke-filled bed is formed in the furnace body, and a fluidized bed of fine ore is formed above the coke-filled bed. By blowing oxygen and circulating gas from the lower part of the furnace body, the fine ore is circulated between a cyclone installed in parallel to the furnace body and pre-reduced, and the pre-reduced fine ore is transferred from the cyclone to the coke. A method of producing iron characterized by introducing the iron into a packed bed and melting and reducing it. (2) A shaft-type shaft with a tuyere at the bottom for blowing oxygen and circulating gas, and a circulating gas outlet at the top, with a coke-filled bed inside and a fluidized bed of fine ore above. a furnace body; a cyclone installed in parallel with the furnace body and connected to the discharge port at the top of the furnace body for separating and collecting fine ore led from the furnace body together with the circulating gas; a separator that separates fine ore collected by the cyclone into pre-reduced ore that has been pre-reduced and unreduced ore that has not yet been pre-reduced; and circulating gas pressure feeding means for blowing into the furnace, the unreduced ore separated by the separator is returned to above the fluidized bed, and the unreduced ore is circulated between the furnace main body and the cyclone. . A steel manufacturing apparatus, characterized in that the pre-reduced ore separated by the separator is blown into the coke packed bed from the tuyere together with oxygen. (3) An upper tuyere and a lower tuyere are provided in the lower part of the furnace body, and the pre-reduced ore separated by the separator is blown into the coke packed bed together with oxygen from the lower tuyere, and the circulating gas and oxygen are injected into the upper part of the furnace body. 3. The iron manufacturing apparatus according to claim 2, wherein the iron making apparatus is configured to be blown into the furnace body from the tuyeres, and the amount of oxygen blown from the upper tuyere and the lower tuyere can be adjusted respectively.