KR20120094945A - Material segregation apparatus for blast furnace top bunker - Google Patents

Abstract

The raw material segregation apparatus of the blast furnace top bunker which can load raw material in the vicinity of the inner wall of a bunker, and can raise raw material segregation effect is provided. The segregation distributor 6 which is rotatable about the vertical axis 20 of the center of the cross section of the bunker 2 and which receives the charging raw material 3 charged from above is larger than the angle of repose of the charging raw material 3. By forming in the upper part in the said bunker 2, when changing the direction of the segregation distributor 6, there is no possibility that the segregation distributor 6 may interfere with the inner wall of the bunker 2, and the The charging raw material dropping opening 14 can be brought close to the inner wall of the bunker 2, and the segregation distributor 6 can be brought into a conical cylinder in the downward direction of the axis 18 and the inner wall side of the bunker 2; By making the part cut out, the fall port 14 of the charging raw material 3 can be stabilized, and the interference with the inner wall of the bunker 2 can be reliably avoided.

Description

Raw material segregation apparatus of blast furnace roadbed bunker {MATERIAL SEGREGATION APPARATUS FOR BLAST FURNACE TOP BUNKER}

BACKGROUND OF THE INVENTION Field of the Invention The present invention relates to a bunker of a charged raw material formed on the hearth of a blast furnace, and is particularly suitable for charging a raw material into a bunker while segregating the raw material.

In the hearth of a blast furnace, a plurality of bunkers which separately store charged raw materials, for example, iron ore and coke, are formed. In Patent Document 1 described below, the blast furnace is controlled by controlling the opening degree of the flow rate adjustment gate at the lower end of the bunker and the turning speed of the distribution chute below it based on the raw material conditions, the distribution pattern, and the raw material outflow characteristics. The degree of freedom of distribution of raw materials for the interior is increased.

By the way, the segregation technique of the raw material charged to blast furnace top bunker is developed. Specifically, the particle size of the raw material can be segregated by setting the charging position of the raw material. And by segregating the particle size of the raw material in a bunker in this way, it becomes possible to control the charging characteristic to a blast furnace. In order to segregate the raw material in the bunker, Patent Document 2 below forms a segregation plate which is rotatable around the horizontal axis below the insertion hole of the bunker, and changes the inclination angle of the segregation plate or the direction of the inclination. In addition, segregation of raw materials in the bunker is controlled.

Japanese Patent Laid-Open No. 54-31005 Japanese Laid-Open Patent Publication 2008-179899

However, since the segregation plate which can rotate around the horizontal axis described in the said patent document 2 may interfere with the inner wall of a bunker at the time of the rotation, length is regulated and it is not possible to make a raw material load in the vicinity of the inner wall of a bunker, There is a problem in that the segregation effect of the raw material is limited.

The present invention has been made in view of the above problems, and an object of the present invention is to provide a raw material segregation apparatus for a blast furnace top bunker, which is capable of charging a raw material directly to the inner wall of the bunker and enhancing the segregation effect of the raw material. .

MEANS TO SOLVE THE PROBLEM In order to solve the said subject, this invention is a segregation apparatus which segregates and loads a raw material in the bunker formed on the furnace top of a blast furnace, Comprising: The upper and lower sides which receive the raw material which can rotate around the vertical axis of the cross section center part of the said bunker, and receive the charged material upwards. It provides a raw material segregation apparatus for a blast furnace hearth bunker characterized by having a segregation distributor on the upper side in the bunker having a direction lower side larger than the angle of repose of the raw material.

It is preferable that the segregation distributor has a shape in which an axial line is a truncated cone cylinder in the inclined downward direction, and the inner wall side portion of the bunker is cut out.

It is preferable that the inclination angle of the axis of the segregation distributor is changeable.

It is preferable that the segregation distributor rotates around the vertical rotation axis by a motor connected to the vertical rotation axis formed in the center of the cross section of the bunker.

It is preferable that the segregation distributor be tilted vertically around the horizontal rotation shaft by a motor connected to the horizontal rotation shaft.

According to the raw material segregation apparatus of the blast furnace hearth bunker of this invention, the segregation distributor which is rotatable about the vertical axis of the center part of the cross section of a bunker, and has a segregation distributor whose upper and lower direction which receives raw material charged upward is larger than the angle of repose of the said raw material is the said bunker. By forming in the upper part of the inside, when changing the direction of the segregation distributor, there is no fear that the segregation distributor will interfere with the inner wall of the bunker. As a result, the raw material dropping port of the segregation distributor can be brought near the inner wall of the bunker. As a result, the segregation of raw materials can be enhanced.

In addition, by setting the segregation distributor in a shape in which the axis of the conical barrel is inclined downward and cuts the inner wall side portion of the bunker, the drop opening of the raw material can be stabilized and the interference with the inner wall of the bunker is assured. Can be avoided.

Moreover, by making it possible to change the inclination angle of the axis line of a segregation distributor, the fall opening of a raw material can be adjusted freely and control of a segregation effect is attained.

BRIEF DESCRIPTION OF THE DRAWINGS It is a longitudinal cross-sectional view which shows one Embodiment of the blast furnace hearth bunker to which the raw material segregation apparatus of this invention was applied.
2 is an explanatory diagram of the segregation distributor of FIG. 1.
It is explanatory drawing of the raw material segregation effect in a bunker. Fig.3 (a) is explanatory drawing which set the dropping port of the charging raw material to the vertical surface side with small slide resistance, and FIG.3 (b) shows setting which set the dropping port of the charging raw material to the slope surface with large sliding resistance. It is also.
4 is an explanatory diagram of a conventional raw material segregation apparatus.

One embodiment of the raw material segregation apparatus of the blast furnace hearth bunker of this invention is demonstrated, referring drawings.

1: is a longitudinal cross-sectional view of the blast furnace top part to which the self-lining structure of this embodiment was applied. A plurality of bunkers 2 are formed above the top of the blast furnace 1. The bunker 2 stores the charging raw material 3 in the blast furnace 1, respectively. Examples of the charging raw material 3 include coke and iron ore. The gate 16 is formed in the upper end part of the bunker 2, and the loading raw material 3 is charged in a bunker by opening this gate 16. FIG. Moreover, the gate 4 is formed in the lower end part of the bunker 2, and the internal charging raw material 3 falls in the blast furnace 1 by opening this gate 4. As shown in FIG. Distributing chute 5 is formed inside the hearth of the blast furnace 1 below the gate 4, and the charging raw material 3 falling by turning this distribution chute 5 is the furnace of the blast furnace 1. Can be distributed within. And in this embodiment, the raw material segregation apparatus of this embodiment is formed inside the bunker 2 above. The raw material segregation apparatus has a segregation distributor 6 which is rotatable about the vertical axis 20 of the cross-section central part of the bunker 2 and whose upper and lower side surfaces 12 which receive the raw material charged upward are larger than the angle of repose of the raw material. Is provided in the upper part in the bunker 2.

2 is a segregation distributor 6 used in the raw material segregation apparatus of the present embodiment. FIG. 2A is a front view of the segregation distributor 6 as in FIG. 1. FIG.2 (b) is a figure seen from the Z arrow direction of FIG.2 (a). FIG.2 (c) is a figure seen from the Y arrow direction of FIG.2 (b). This segregation distributor 6 is a truncated cone cylinder whose axis 18 is inclined downward, and has become the shape which cut off the inner wall side of the bunker 2 shown with a broken line in FIG. Moreover, the up-down direction upper part of this segregation distributor 6 is opened in order to avoid interference with the charging raw material. In the figure, 6a is a charging raw material guide surface of the segregation distributor 6. This segregation distributor 6 is attached to the hanger 7 at the upper part inside the bunker 2. When the charging raw material 3 is charged above the bunker 2, it falls on the upper and lower side 12 of the segregation distributor 6. Since the up-down direction lower side surface 12 of the segregation distributor 6 becomes an angle larger than the angle of repose of the charging raw material 3, the charging raw material 3 which fell on the segregation distributor 6 bunkers at the inclination lower end part. (2) falls in. In addition, although the segregation distributor 6 of this embodiment was made into the cross-sectional shape of circular arc as shown to Fig.2 (c), it is not limited to this, A circular shape, an ellipse shape, and polygonal shape may be sufficient as it.

The said hanger 7 is attached to the vertical rotation shaft 22 formed in the cross-sectional center part of the bunker 2, and the motor 8 is connected to this vertical rotation shaft 22. As shown in FIG. The vertical rotary shaft and the motor 8 need not be directly connected, and may be, for example, provided with a reduction gear mechanism interposed therebetween. As a result, the segregation distributor 6 attached to the hanger 7 rotates in the direction of the arrow a in FIG. 1 around the vertical rotational shaft 22 formed in the center of the cross section of the bunker 2, whereby the segregation distributor 6 ) And the inner wall of the bunker 2 do not interfere, and the direction of the drop port 14 of the charging raw material 3 of the inclined lower end part of the segregation distributor 6 can be changed and adjusted. In addition, the segregation distributor 6 of the present embodiment has a shape in which the axis 18 is in the shape of a truncated cone cylinder in the inclined downward direction and the inner wall side of the bunker 2 is cut off, so that the charging raw material 3 falls ( The dropping port 14 of the inclined lower end part of 6) can be set in the immediate vicinity of the inner wall of the bunker 2.

In addition, the segregation distributor 6 is attached to the hanger 7 freely via a horizontal rotating shaft, and the motor 9 is connected to the horizontal rotating shaft. The horizontal rotating shaft and the motor 9 do not need to be directly connected, and for example, may be provided with a reduction gear mechanism interposed therebetween. As a result, the segregation distributor 6 attached to the hanger 7 can rotate (tilt) in the vertical direction around the horizontal rotation axis, and as a result, the loading raw material 3 of the inclined lower end portion of the segregation distributor 6 is formed. The position of the drop port 14 can be changed and adjusted.

3 is an explanatory diagram of raw material segregation effects in the bunker 2. In the bunker 2 of the figure, in order to make an effect easy to understand, the lower right side slope of each figure shows the one where resistance is large at the time of raw material movement, and the vertical surface of the left side of each figure has shown the one where the resistance is small. . In the case of Fig. 1, the slopes continuous toward the gate 4 have a small resistance of the raw material slide, and once the curved slopes have a large resistance of the raw material slide.

When the charging raw material 3 is charged in the narrow fall opening 14, the charging raw material 3 is going to deposit in a mountain type. The slope angle of this mountain deposition state is the angle of repose. When various particle sizes are mixed in the charging raw material 3, the charging raw material 3 with a large particle size falls along the slope of an acidic deposition state, and the charging raw material 3 with a small particle size is of the acidic deposition state. Stay on top This is the raw material segregation effect called percolation. It is known that percolation has an effect that the longer the slope length of a mountain deposition state is.

FIG. 3A sets the dropping port 14 of the charging raw material 3 to the vertical surface side with small sliding resistance, and FIG. 3B shows the dropping opening of the charging raw material 3 having a large sliding resistance. The case where it is set to the slope side is shown. In the case of Fig.3 (a), the charging raw material 3 with a large particle size is integrated on the slope side with a large slide resistance, and the charging raw material 3 with a small particle size is integrated on the vertical surface side with a small slide resistance. In this state, when the fall of the charging raw material 3 is started, first, the charging raw material 3 with small particle size falls first, and then the charging raw material 3 with a medium particle size falls, and finally the charging with large particle size is carried out. The raw material 3 falls. On the other hand, in the case of Fig. 3B, the charging raw material 3 having a large particle size is integrated on the vertical surface side having a small sliding resistance, and the charging raw material 3 having a small particle size is integrated on a slope surface having a large sliding resistance. In this state, when the fall of the charging raw material 3 is started, the charging raw material 3 with a large particle size falls first, then the charging raw material 3 with a medium particle size falls, and finally, the charging with small particle size is carried out. The raw material 3 falls.

By using such a raw material segregation effect and a raw material fall particle size effect, the particle size control of the charging raw material 3 in the blast furnace 1 becomes possible. In that case, in the raw material segregation apparatus of the present embodiment, the segregation distributor 6 rotates around the vertical rotation shaft 22 formed in the center of the cross section of the bunker 2, so that the segregation distributor 6 and The inner wall of the bunker 2 does not interfere, and the direction of the dropping opening 14 of the charging raw material 3 of the inclined lower end part of the segregation distributor 6 can be changed and adjusted, and the axis 18 is the inclined downward cone Since the segregation distributor 6 of the shape which cut into the cylinder and the inner wall side of the bunker 2 was cut off is used, the dropping port 14 of the inclined lower end part of the segregation distributor 6 in which the charging raw material 3 falls falls into a bunker ( 2), it can be set in the immediate vicinity of the inner wall, and as a result, the slope length of the form-type deposition state of the charging raw material 3 can be maximized, and a raw material segregation effect is large.

It is a schematic block diagram which shows an example of the raw material segregation apparatus of the conventional blast furnace hearth bunker. The conventional raw material segregation apparatus forms the segregation plate B which can be rotated about a horizontal axis around the bunker 2, for example, receives the charged raw material from segregation plate B, The raw material is slid in the oblique direction to achieve segregation effect. However, the segregation plate B rotatable around the horizontal axis is restricted in length in order to avoid interference with the inner wall of the bunker 2. If the length of the segregation plate B is short, the dropping port of the raw material cannot be set in the immediate vicinity of the inner wall of the bunker 2, and as a result, the slope length of the raw material deposition state becomes short, and the raw material segregation effect is not sufficiently obtained. Problem occurs.

As described above, in the raw material segregation apparatus of the blast furnace hearth bunker of the present embodiment, the up-down direction lower surface receiving the charging raw material 3 which is rotatable about the vertical axis 20 of the cross-section central portion of the bunker 2 and is charged upwards ( 12) Since the segregation distributor 6 larger than the angle of repose of the said charging raw material 3 was formed in the upper part in the said bunker 2, when the direction of the segregation distributor 6 is changed, the said segregation distributor 6 is carried out. There is no fear of interfering with the inner wall of the bunker 2, and as a result, the charging raw material fall opening 14 of the segregation distributor 6 can be brought close to the inner wall of the bunker 2, thereby improving the raw material segregation effect. It can increase.

Moreover, since the segregation distributor 6 was made into the shape in which the axis line 18 was the inclined cylindrical cone of the inclined downward direction, and the inner wall side part of the bunker 2 was cut out, the fall port 14 of the charging raw material 3 was made into In addition to stabilization, interference with the inner wall of the bunker 2 can be reliably avoided.

Moreover, since the inclination angle of the axis line 18 of the segregation distributor 6 can be changed, the fall opening 14 of the charging raw material 3 can be adjusted freely, and the segregation effect can be controlled.

In addition, the segregation distributor 6 is rotated around the vertical rotation shaft 22 by the motor 8 connected to the vertical rotation shaft 22 formed in the center of the cross section of the bunker 2 to thereby drop the charging raw material 3. The sphere 14 can be adjusted freely, and the segregation effect can be controlled.

In addition, by tilting the segregation distributor 6 in the vertical direction around the horizontal rotation shaft by the motor 9 connected to the horizontal rotation shaft, the drop opening 14 of the charging raw material 3 can be freely adjusted, and the segregation effect is controlled. Becomes possible.

1: blast furnace
2: bunker
3: charging raw materials
4: Gate
5: dispensing suit
6: segregation divider
6a: charging raw material guide surface of segregation distributor
7: hanger
8, 9: motor
12: up and down direction
14: dropping hole of the raw material
16: gate
18: axis of segregation distributor
20: vertical axis
22: vertical rotation axis

Claims (5)

A segregation apparatus which segregates and loads raw materials into a bunker formed on the blast furnace top, wherein segregation of the upper and lower sides of the bunker which is rotatable about a vertical axis of the center of the cross section of the bunker and which receives raw materials charged upward is larger than the angle of repose of the raw materials. The raw material segregation apparatus of the blast furnace hearth bunker characterized by including the distributor in the upper part in a bunker. The method of claim 1,
The segregation distributor is a circumferential cone-shaped cone cylinder in the inclined downward direction and has a shape in which the inner wall side portion of the bunker is cut out. The method of claim 2,
The raw material segregation apparatus of the blast furnace hearth bunker which made it possible to change the inclination angle of the axis of the segregation distributor. The method of claim 1,
The segregation distributor rotates around the vertical rotation shaft by a motor connected to the vertical rotation shaft formed in the center of the cross section of the bunker. The method of claim 1,
The segregation distributor is tilted in the vertical direction around the horizontal rotation shaft by a motor connected to the horizontal rotation shaft, so the raw material segregation apparatus of the blast furnace hearth bunker.

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