JP2021195617A - Furnace top bunker and raw material charging method for blast furnace - Google Patents

Abstract

To provide a furnace top bunker capable of realizing a raw material grain size distribution in the furnace top bunker suitable for reverse tilt charging.SOLUTION: A structure having a predetermined shape is arranged in a raw material storage part of a top bunker.SELECTED DRAWING: Figure 1

Description

The present invention relates to a furnace top bunker disposed at the top of a blast furnace and a method for charging raw materials for the blast furnace.

In a blast furnace, as shown in FIG. 1, normally, ore raw materials such as sinter, pellets, and massive ore and coke are alternately charged from the top in layers to form an ore layer and a coke layer, and feathers are formed. The operation of obtaining pig iron by flowing a high-temperature reducing gas upward from the mouth is performed. Hereinafter, the ore raw materials and coke are collectively referred to as raw materials. In the figure, reference numeral 1 is a blast furnace, 2 is a tuyere, 3 is an ore layer, 4 is a coke layer, and 5 is a fusion layer.

In the operation of such a blast furnace, the gas flow in the blast furnace affects the reduction efficiency of the ore raw material and the amount of heat dissipated to the outside of the blast furnace. In general, in order to improve the reduction efficiency of the ore raw material and reduce the amount of heat dissipated to the outside of the blast furnace, it is desirable to flow more gas near the center of the blast furnace.

There are two main reasons for this.
(1) When the gas flow rate near the furnace wall of the blast furnace increases, the amount of heat dissipated to the outside of the blast furnace increases and the energy efficiency decreases.
(2) In the lower part of the blast furnace, the ore raw material charged in the blast furnace is heated and reduced by the reducing gas to form a fusion zone. The fusion zone is a region in which a fusion layer having a bedrock-like structure in which particles of ore raw materials are fused to each other and coke slits in which coke is present alone are alternately present. As described above, the fused layer has a rock-like structure in which particles of ore raw materials are fused to each other, so that the void ratio in the layer is extremely low. On the other hand, the void ratio of the coke slit is higher than that of the fused layer. Therefore, in the fusion zone, the gas flowing from below in the vertical direction selectively flows through the coke slit. Here, as the amount of gas flowing near the center of the blast furnace increases, the height region of the fusion zone is expanded. As a result, the number of coke slits in the cohesive zone is increased, and the air permeability of the gas is improved.

In order to increase the gas flow rate near the center of the blast furnace, it is effective to place the large particle size raw material near the center and the small particle size raw material near the furnace wall in the radial direction of the blast furnace. ..
This is because when the packed layer of large particle size particles is compared with the packed bed of small particle size particles, the former has a smaller total specific surface area of the packed particles, that is, in the packed layer. This is because the friction between the flowing gas and the particles is reduced and the gas flow rate is increased.

Therefore, various techniques have been proposed for controlling the particle size distribution and the layer thickness of the ore layer and the coke layer formed in the blast furnace to increase the gas flow rate near the center of the blast furnace. ..

For example, in Patent Document 1,
"It is a method of charging raw materials for a blast furnace using a bellless type charging device equipped with a swivel chute and bunker arranged in parallel on the top of the furnace.
When charging the raw material into the furnace through the furnace top bunker that temporarily stores the raw material to be charged into the blast furnace and discharges it to the swivel chute provided below it.
When a movable plate that can be tilted is provided in the furnace top bunker, the raw material charged into the furnace top bunker is made to collide with the movable plate, and the tip of the swivel chute is tilted from the periphery in the blast furnace toward the center. Operates the movable plate so that the drop direction of the raw material is the direction of the discharge b of the furnace top bunker, and the drop position of the raw material charged into the furnace top bunker is directly set to the discharge port of the raw material. As the upper part, in the furnace top bunker, fine particles gather near the discharge port due to the accumulation characteristics of the raw material, and coarse particles gather at a position away from that.
When the tip of the swivel chute is tilted from the center of the blast furnace toward the periphery, the movable plate is operated so that the falling direction of the raw material is opposite to the discharge b of the furnace top bunker, and the furnace top is operated. The drop position of the raw material charged into the bunker is set as a side wall away from the discharge port, so that the coarse grain raw material gathers near the discharge port and the fine particles gather far from the discharge port.
A method for charging raw materials for a blast furnace using a furnace top bunker and a bellless type charging device, which comprises depositing coarse particles in the center of the blast furnace. "
Has been proposed.

Patent No. 4591520

By the way, in the bellless type blast furnace as shown in FIG. 2, a furnace top bunker for temporarily storing raw materials to be charged into the blast furnace is arranged at the top portion of the blast furnace. Then, the flow rate adjusting gate is opened and the raw material discharged from the furnace top bunker is charged into the blast furnace via the collecting hopper and the swivel chute. At this time, the tip position in the radial direction of the swivel chute may be changed (hereinafter, also referred to as tilting) to adjust the drop position of the raw material in the radial direction of the blast furnace.
In the figure, reference numeral 6 is a furnace top bunker, 7 is a flow rate adjusting gate, 8 is a collective hopper, and 9 is a swivel chute.

That is, when the raw material is charged into the blast furnace, the swivel chute tilts at regular intervals while swirling at a constant speed in the circumferential direction of the blast furnace with the axis of the blast furnace as the axis of rotation. The types of tilting are roughly divided into two types: forward tilting charging when tilting from the vicinity of the furnace wall of the blast furnace to the center of the blast furnace, and reverse tilting from the center of the blast furnace to the vicinity of the furnace wall of the blast furnace. It is called tilting charging.

Of these, the reverse tilt charging has the effect of suppressing the raw material from flowing into the center of the blast furnace after the raw material is charged and deposited in the blast furnace. Therefore, the reverse tilting charge is more likely to stabilize the raw material deposit shape than the forward tilting charge, and is advantageous in controlling the raw material particle size distribution in the blast furnace.

As mentioned above, from the viewpoint of increasing the gas flow rate near the center of the blast furnace, in the radial direction of the blast furnace, the large particle size raw material is placed near the center and the small particle size raw material is placed near the furnace wall of the blast furnace. It is effective to arrange it. In the present specification, auxiliary raw materials such as coke, ore (including agglomerated ore) charged from the top of the blast furnace, and limestone are collectively referred to as raw materials. For all of these raw materials, it is most preferable to place a large particle size in the center of the blast furnace, but the coke, ore, and one or more of the coke and ore mixture are large in the center. It is also effective to arrange the one with the particle size.
Raw materials per batch are usually stored in the furnace top bunker. Therefore, in the case of reverse tilt charging, it is preferable to have a raw material particle size distribution in the furnace top bunker so that a large number of large particle size raw materials are discharged at the initial stage of raw material discharge from the furnace top bunker.

In this regard, the technique of Patent Document 1 intentionally segregates the raw material stored in the furnace top bunker by using a tiltable movable plate (hereinafter, also referred to as a segregation control plate) provided in the furnace top bunker. As a result, it is intended to realize a preferable raw material particle size distribution in the furnace top bunker according to the tilting method.

However, the technique of Patent Document 1 cannot sufficiently realize the particle size distribution of the raw material in the furnace top bunker suitable for reverse tilt loading, that is, the raw material discharged from the furnace top bunker in the middle to the final stage of raw material discharge. A certain number of large particle size raw materials were mixed, and as a result, a certain number of large particle size raw materials were mixed in the vicinity of the furnace wall of the blast furnace.

The present invention has been developed in view of the above-mentioned current situation, and is suitable for reverse tilting charging, and is capable of realizing a raw material particle size distribution in a furnace top bunker. The purpose is to provide it together with a method of charging raw materials for a blast furnace using a top bunker.

Now, the inventors have made extensive studies to achieve the above-mentioned purpose.
First, the inventors investigated the reason why the raw material particle size distribution in the furnace top bunker suitable for reverse tilt loading may not be sufficiently realized in the technique of Patent Document 1.
Generally, from the viewpoint of making the collective hopper that receives the raw material discharged from the furnace top bunker compact and strengthening the particle size segregation in the bunker, the raw material discharge port of the furnace top bunker is a horizontal plane as shown in FIG. In (projection plane in the vertical direction), it is arranged eccentrically from the center of the raw material storage unit to the axial center side of the blast furnace. Note that FIG. 3 is a schematic view showing the arrangement of each part of the furnace top bunker when viewed from above in the vertical direction. In the figure, 6-1 is a raw material storage section and 6-2 is a raw material discharge port.
Here, the eccentric direction is the direction from the center of the raw material storage portion toward the center of the raw material discharge port on the horizontal plane, and the first direction is a direction rotated by 90 ° clockwise from the eccentric direction when viewed from above in the vertical direction. The direction, the direction rotated by 180 °, is called the direction opposite to the eccentricity, and the direction rotated by 270 ° is called the second direction. Since the raw material discharge port of the furnace top bunker is arranged eccentrically from the center of the raw material storage section to the axial center side of the blast furnace on the horizontal plane (projection surface in the vertical direction), the furnace top bunker is arranged at the top of the blast furnace. In this state, the eccentric direction is usually the same as the direction from the center of the raw material storage unit toward the blast furnace axis (hereinafter, also referred to as the blast furnace axis direction).

When reverse tilting loading is performed by the technique of Patent Document 1, as shown in FIG. 4, the falling direction of the raw material is the wall portion on the horizontal plane opposite to the raw material discharge b of the furnace top bunker, that is, the wall portion on the opposite side of the eccentricity. Hereinafter, the segregation control plate is operated so as to be in the vicinity of the side wall opposite to the eccentricity. Therefore, the shape of the raw material deposit layer in the furnace top bunker is such that the raw material deposit surface is vertical toward the eccentric direction (from the eccentric opposite side wall portion to the eccentric side wall portion (hereinafter, also referred to as eccentric side wall portion)). It will incline downward in the direction. In the figure, 6-3 is a segregation control plate.

In this case, the particle size distribution of the raw material in the top bunker and the order of raw material discharge when the raw material is discharged from the top bunker (the discharge time for each raw material storage position in the top bunker) are measured by a numerical simulation called the discrete element method. As a result of calculation, as shown in FIG. 5, more than half of the large particle size raw materials gather in the vicinity of the raw material discharge port, that is, in the region where the raw material is discharged at the initial stage of raw material discharge. However, most of the rest of the large particle size raw material is the wall portion on the first direction and the second direction side (hereinafter, the first wall portion and the second wall portion) which are the directions perpendicular to the eccentric direction of the furnace top bunker. It was found that it is located in the vicinity of the part), that is, in the area where the raw material is discharged from the middle to the end. That is, it was found that due to this, when reverse tilting charging was performed, a certain number of large particle size raw materials were mixed in the vicinity of the furnace wall of the blast furnace.

Based on this point, the inventors further examined and found that
-Disperse the drop position of the raw material charged in the furnace top bunker not only in the vicinity of the side wall opposite the eccentricity but also in the vicinity of the first wall and the second wall.
-As a result, as shown in FIG. 6, the shape of the raw material deposit layer in the furnace top bunker is changed to the raw material discharge b not only from the side wall opposite the eccentricity but also from the first wall portion and the second wall portion. Inclining downward in the vertical direction, in other words, the shape of the raw material sedimentary layer is roughly shaped like a mortar.
Was found to be effective.
Then, it was found that the large particle size raw material can be collected more closely in the vicinity of the raw material discharge port.

The inventors consider the above reason as follows.
That is, the large particle size raw material tends to roll more easily on the deposited surface than the small particle size raw material. Therefore, by distributing the drop position of the raw material charged into the furnace top bunker not only in the vicinity of the side wall opposite to the eccentricity but also in the vicinity of the first wall portion and the second wall portion, the first wall portion and the first wall portion and the vicinity are dispersed. A raw material deposit layer is formed that inclines downward in the vertical direction from the second wall portion toward the raw material discharge pot. Then, while the large particle size raw material gradually charged rolls on this deposited surface, the small particle size raw material is deposited at the drop position, so that the large particle size raw material can be more densely collected in the vicinity of the raw material discharge port.

Then, based on the above findings, a method for dispersing the drop position of the raw material charged in the furnace top bunker not only in the vicinity of the side wall opposite the eccentricity but also in the vicinity of the first wall portion and the second wall portion. After considering,
A structure having a raw material collision surface is placed inside the raw material storage section of the furnace top bunker.
As shown in FIG. 7, the shape of the raw material collision surface is formed from the top of the structure at least in the opposite direction of eccentricity and in the first direction and the second direction perpendicular to the opposite direction of eccentricity and the vertical direction, respectively. Tilt downward toward the end of the collision surface,
Was found to be effective. In the figure, 6-4 is a structure and 6-5 is a raw material collision surface.
The present invention has been completed with further studies based on the above findings.

That is, the gist structure of the present invention is as follows.
1. 1. A furnace top bunker located at the top of a blast furnace.
The furnace top bunker
Raw material storage section and
A raw material charging inlet for charging raw materials into the raw material storage section from above the raw material storage section,
A structure which is arranged inside the raw material storage portion and has a raw material collision surface on which raw materials charged from the raw material charging inlet collide with each other.
A raw material discharge port that discharges the raw material in the raw material storage unit below the raw material storage unit, and
With
The raw material discharge port is arranged eccentrically from the center of the raw material storage portion on a horizontal plane.
Further, the raw material colliding surface of the structure is at least in the direction opposite to the eccentricity, and in the first direction and the second direction perpendicular to the opposite direction of the eccentricity and the vertical direction, respectively, from the top of the structure to the raw material. A furnace top bunker that slopes downward toward the end of the collision surface.
Here, the direction opposite to the eccentricity is the direction opposite to the direction in which the raw material discharge port is eccentric from the center of the raw material storage portion on the horizontal plane.

2. 2. The furnace top bunker according to 1 above, wherein the inclination angle α from the horizontal direction of the line segment connecting the top of the structure and the end of the raw material collision surface in the direction opposite to the eccentricity is 25 to 45 °.

3. 3. The horizontal inclination angles β and γ of the line segment connecting the top of the structure and the end of the raw material collision surface in the first direction and the second direction are 25 to 45 °, respectively. The furnace top bunker according to 1 or 2 above.

4. The furnace top bunker according to any one of 1 to 3 above, wherein the top of the structure is located in the range of 0 to 0.6 in a dimensionless distance (r / R) from the center of the raw material storage portion in a horizontal plane. ..
Here, the dimensionless distance (r / R) is a value obtained by dividing the distance (r) from the center of the raw material storage portion in the horizontal plane by the inner radius (R) of the raw material storage portion.

5. It is a method of charging raw materials for a blast furnace.
The blast furnace has one or more furnace top bunker according to any one of 1 to 4 at the top of the furnace.
In addition, the method of charging raw materials for the blast furnace is
A step of charging a raw material into the raw material storage unit from the raw material charging port of the furnace top bunker, causing the raw material to collide with the structure, and then storing the raw material in the raw material storage unit.
It is provided with a step of discharging the raw material stored in the raw material storage unit from the raw material discharge port and charging the discharged raw material into the blast furnace via the swirling chute of the blast furnace.
How to charge raw materials for blast furnace.

According to the present invention, it is possible to realize a raw material particle size distribution in a furnace top bunker, which is suitable for reverse tilt loading. As a result, when the blast furnace is in operation, the gas flow rate in the vicinity of the center of the blast furnace can be increased regardless of the tilting method, and the air permeability and the reduction efficiency can be further improved.
Further, the present invention does not require strict control or a complicated structure in the furnace top bunker, which is a high-pressure container, and is therefore excellent in terms of maintainability.

It is a schematic diagram which shows the gas flow in a blast furnace. It is a schematic diagram which shows the procedure of charging a raw material into a blast furnace. It is a schematic diagram which shows the arrangement of each part of the furnace top bunker when viewed from above in the vertical direction. It is a schematic diagram which shows the raw material accumulation state in the furnace top bunker when the raw material is charged into the furnace top bunker which installed the segregation control plate. (A) is a schematic view when viewed from an eccentric direction, and (b) is a perspective view. Distribution of raw material particle size in the top bunker when the raw material is charged into the top bunker with the segregation control plate, and the order of raw material discharge when the raw material is discharged from the top bunker (raw material storage in the top bunker) It is a numerical simulation result of the discharge time for each position). It is a schematic diagram which shows the raw material deposition state in the furnace top bunker suitable for reverse tilt loading. (A) is a schematic view when viewed from an eccentric direction, and (b) is a perspective view. It is a schematic diagram which shows an example of the furnace top bunker according to one Embodiment of this invention. It is a schematic diagram which shows an example of the shape (outer circumference shape) from the top of a structure to the end of a raw material collision surface. It is a schematic diagram which shows the example of the structure installed in the furnace top bunker according to one Embodiment of this invention. It is a schematic diagram which shows the example of the structure installed in the furnace top bunker according to one Embodiment of this invention. It is a schematic diagram which shows an example of the case where the dispersion adjustment plate is installed in the structure. It is a schematic diagram which shows the suitable area in which the top of a structure is located. The particle size distribution of the raw material in the top bunker when the raw material is charged into the top bunker according to conditions 1 and 2, and the raw material discharge order when the raw material is discharged from the top bunker (raw material storage position in the top bunker). It is a numerical simulation result of (emission time for each). It is a figure which plotted the numerical simulation result of the raw material distribution state in the blast furnace when the raw material is charged into the blast furnace under conditions 1 and 2. It is a numerical simulation result of the pressure loss at the top of the furnace when the blast furnace is operated under the conditions 1 and 2. It is a schematic diagram of the apparatus used for a model experiment. It is a schematic diagram which shows the particle size distribution of a raw material obtained by a model experiment. It is a schematic diagram which shows the preferable range of the apex position of a raw material sedimentary layer.

The present invention will be described based on the following embodiments.

[Fire pot bunker]
As shown in FIG. 2, the furnace top bunker according to an embodiment of the present invention is arranged at the top of the blast furnace and temporarily stores the raw materials to be charged into the blast furnace. In general, two or three top bunker are arranged in parallel at the top of the blast furnace.

The furnace top bunker according to the embodiment of the present invention is as shown in FIG.
Raw material storage section and
A raw material charging inlet (not shown) for charging the raw material into the raw material storage section from above the raw material storage section,
A structure which is arranged inside the raw material storage portion and has a raw material collision surface on which raw materials charged from the raw material charging inlet collide with each other.
A raw material discharge port that discharges the raw material in the raw material storage unit below the raw material storage unit, and
To prepare.
The terms upper, lower, upper and lower shall mean upper, lower, upper and lower in the vertical direction unless otherwise specified.

Here, the raw material charging inlet is arranged above the raw material storage section. The position of the raw material charging inlet on the horizontal plane is not particularly limited, but is generally located on the axial side of the blast furnace (in the same direction as the raw material discharge port) from the central position of the raw material storage section.

Then, the raw material charged from the raw material charging inlet collides with the raw material collision surface of the structure arranged inside the raw material storage section, then falls into the raw material storage section and is temporarily stored in the raw material storage section. To. The raw material temporarily stored in the raw material storage unit is usually one batch. Further, the raw material storage portion has a body portion having a cylindrical shape, a truncated cone cylinder shape, or a combined shape thereof, and a reduced diameter portion whose diameter decreases downward.
The maximum diameter (outer diameter) of the furnace top bunker is usually about 4000 to 5000 mm, and the height of the furnace top bunker is about 9000 to 13000 mm.

Then, according to the operation of the blast furnace, the flow rate adjustment gate is opened, and the raw material is gradually discharged from the raw material discharge port at the lower end of the reduced diameter portion of the raw material storage section by the weight of the raw material, via the collecting hopper and the swivel chute. , Raw materials are charged into the blast furnace.

As shown in FIG. 3, the raw material discharge port is eccentric from the center of the raw material storage section in the horizontal plane. Normally, the distance between the center of the raw material storage section and the raw material discharge port in the horizontal direction (eccentricity amount): A is the raw material. Inner radius of the reservoir: 0.60 to 0.70 times R. Further, the inner radius of the raw material discharge port: B is usually 0.30 to 0.50 times the inner radius of the raw material storage portion: R. The center position and inner diameter of the raw material storage portion are based on the installation height position of the top of the structure described later. Further, the center position and the inner diameter of the raw material discharge port are based on the height position connected to the lower end of the raw material storage portion. The same applies thereafter.
In FIG. 3, an example in which the horizontal cross section of the raw material storage portion is circular has been described, but in the case of other shapes, the center of the raw material storage portion is the center of gravity of the horizontal cross section which is the maximum area. In this case, the eccentric direction is the direction from the center of the raw material storage section connecting the center of the raw material discharge port and the center of the raw material storage section in the horizontal cross section (horizontal cross section having the maximum area) toward the center of the raw material discharge port. , R shall be 1/2 of the length of the raw material storage portion in the eccentric direction of the horizontal cross section.

In the furnace top bunker according to the embodiment of the present invention, the shape of the raw material collision surface of the above structure is extremely important.
Specifically, as shown in FIG. 7, the shape of the raw material collision surface is at least in the opposite direction of eccentricity, in the first direction perpendicular to the eccentric direction and the vertical direction, and in the second direction, respectively, as a structure (raw material). It is important to incline downward from the top of the collision surface) toward the end of the raw material collision surface.

That is, as described above, in the case of reverse tilt loading, as shown in FIG. 6, the drop position of the raw material charged in the furnace top bunker is set not only in the vicinity of the side wall opposite to the eccentricity but also in the first wall portion. And also distributed near the second wall, thereby changing the shape of the raw material deposit layer in the furnace top bunker not only from the eccentric opposite side wall but also from the first wall and the second wall. It is important to incline downward in the vertical direction toward the raw material discharge pot, in other words, to make the shape of the raw material deposit layer abbreviated into a mortar shape. As a result, the large particle size raw material can be collected more closely in the vicinity of the raw material discharge port.
Therefore, the shape of the raw material collision surface of the structure (outer peripheral shape of the vertical cross section) is changed from the top of the structure to the end of the raw material collision surface not only in the direction opposite to the eccentricity but also in the first direction and the second direction, respectively. It is important to incline downward toward.
At this time, as shown in FIG. 18, the direction from the first direction to the second direction through the opposite direction of eccentricity (direction between 90 ° and 270 ° clockwise from the eccentric direction). The shape of the raw material deposit layer formed in 1 is preferably such that the apex position of the raw material deposit layer is in the range of 20 to 50 mm from the inner wall of the bunker in any direction. This is because when the apex position of the raw material deposit layer formed in the above direction moves away from the inner wall of the bunker, the large particle size raw material tends to segregate toward the inner wall of the bunker, in other words, the large particles collected near the raw material discharge port. This is because the raw material for diameter may be reduced.

Here, in the direction opposite to the eccentricity, inclining downward from the top of the structure toward the end of the raw material collision surface means that, as shown in FIG. 7, the vertical cross section of the structure at the position passing through the top of the structure is the first. When viewed from the direction of 1, it means that the structure is inclined downward from the top of the structure toward the end of the raw material collision surface. Similarly, tilting downward from the top of the structure toward the end of the raw material collision surface in the first and second directions means that the structure is located through the top of the structure, as shown in FIG. When the vertical cross section is viewed from the eccentric direction, it means that the structure is inclined downward from the top of the structure toward the end of the raw material collision surface in the first direction and the second direction. Alternatively, it means that the structure is inclined downward from the highest position of the raw material collision surface toward the end in the cross section along the first direction and the second direction.

The raw material collision surface is the upper surface of the structure (the region of the structure when viewed from above). Therefore, the top of the structure is at the highest position in the vertical direction of the raw material collision surface. Here, when there are a plurality of highest positions on the raw material collision surface, the point at the highest position, which is the farthest from the raw material discharge port in the eccentric direction, is set as the top. However, when the dispersion adjusting plate described later is arranged in the structure, the region of the dispersion adjusting plate is excluded from the raw material collision surface. In addition, members for fixing the structure shall be excluded from the raw material collision surface. The raw material collision surface may be composed of one continuous surface or may be composed of a plurality of surfaces.

Further, the inclination angle α from the horizontal direction of the line segment connecting the top of the structure and the end of the raw material collision surface in the direction opposite to the eccentricity is preferably 25 to 45 °. α is more preferably 40 to 43 °.

Further, it is preferable that the inclination angles β and γ from the horizontal direction of the line segment connecting the top of the structure and the end of the raw material collision surface in the first direction and the second direction are 25 to 45 °, respectively. .. β and γ are more preferably 40 to 43 °, respectively.

Similarly, the raw material collision surface from the top of the structure in the direction from the first direction, through the opposite direction of eccentricity, to the second direction (direction between 90 ° and 270 ° clockwise from the eccentric direction). The shape up to the end of the structure is also preferably inclined downward from the top of the structure toward the end of the raw material collision surface. Suitable tilt angles from the horizontal direction of the straight line connecting the top of the structure and the end of the raw material collision surface in these directions are also the same as the tilt angles α, β and γ described above.

The shape (outer peripheral shape) from the top of the structure to the end of the raw material collision surface in each vertical cross section of the structure does not have to be a constant inclination regardless of the direction, and is shaped so that the inclination changes variously. For example, as shown in FIG. 8, the shape may be an arc shape or a shape in which the inclination changes stepwise.

In addition, the direction from the first direction through the eccentric direction to the second direction (clockwise from the eccentric direction between 0 and 90 °, 270 ° to 360 °, but the first. The shape from the top of the structure to the end of the raw material collision surface in (excluding the direction and the second direction) is not particularly limited.
For example, it may be inclined downward from the top of the structure toward the end of the raw material collision surface as in the opposite direction of eccentricity and the first and second directions. In this case, the shape of the structure is, for example, a cone, an oblique cone, an elliptical cone, a shape in which a cone is attached to the upper part of a truncated cone (shape 1), or a half-split cone, as shown in FIG. A shape in which a half-split elliptical cone is bonded to each other (shape 2), a dome shape in which the raw material collision surface is spherical, a polyhedron shape, and a shape in which these shapes are cut in the vertical direction at an arbitrary position, etc. Become. The inside of the structure may be hollow, and the member may not be arranged on a surface other than the material collision surface such as the bottom surface and the side surface. Further, the above-mentioned shape includes a shape changed by providing a member on the bottom surface or the like as long as the region of the raw material collision surface does not change.

Further, in the vertical projection region of the structure, the direction (clockwise from the eccentric direction) from the first direction through the eccentric direction to the second direction with the top of the structure as the center. In a direction between 0 to 90 ° and 270 ° to 360 °, except for the first direction and the second direction), in a shape in which the raw material collision surface does not exist in all or a part thereof. There may be. In this case, the shape of the structure is, for example, a semi-conical shape, a semi-elliptical cone shape, a shape in which a cone is attached to the upper part of a truncated cone, cut in half (shape 3), and a raw material collision, as shown in FIG. The dome shape whose surface is spherical is halved (semi-dome shape), and the shape is a polyhedron. The inside of the structure may be hollow, and the member may not be arranged on a surface other than the material collision surface such as the bottom surface and the side surface. Further, the above-mentioned shape includes a shape changed by providing a member such as a bottom surface as long as the region of the raw material collision surface does not change.
Further, it does not have to be inclined downward from the top of the structure toward the eccentric direction. For example, a structure as shown in FIG. 10 may be used. The shape 4 arranges the semi-cone so as to incline downward in the opposite direction of the eccentricity, the first direction and the second direction, and in the eccentric direction of the semi-cone, the triangular prism is arranged in the first direction and the second direction. It is a shape arranged so as to incline downward only.

Further, as shown in FIG. 11, in order to prevent the raw material from falling to the raw material discharge port side, a dispersion adjusting plate may be separately provided on the eccentric direction side of the structure. In the figure, reference numeral 6-6 is a dispersion adjusting plate.

In addition, the length of the above structure (distance between the ends of the raw material collision surfaces in the horizontal direction when the structure is viewed from the first direction) a is 0. It is preferably 4 to 0.8 times (see FIG. 7, the same applies to the width and height of the structure described later). The width of the above structure (distance between the ends of the raw material collision surfaces in the horizontal direction when the structure is viewed from the eccentric direction) b is 0.4 to 0.8 times the inner radius of the raw material storage portion: R. Is preferable. The height h (distance from the lower end to the top of the raw material collision surface) of the above structure is preferably 0.47 to 1.0 times the length of the structure: a.

The shape of the structure may be symmetrical or asymmetrical in the first direction and the second direction.

Further, the raw material charged from the raw material inlet of the furnace top bunker usually falls near the center of the furnace top bunker unless the above structure is installed. Therefore, regarding the horizontal installation position of the above structure, as shown in FIG. 12, the top of the structure has a dimensionless distance (r / R) of 0 to 0.6 from the center of the raw material storage portion. It is preferably located in the range.
Here, the dimensionless distance (r / R) is the distance (r) from the center of the raw material storage portion in the horizontal plane (projection plane in the vertical direction) divided by the inner radius (R) of the raw material storage portion. The value.

In addition, the installation position of the above structure in the vertical direction is not particularly limited, but the dimensionless height (h'/ H) at the top of the structure is in the range of 0.75 to 0.85. It is preferably inside.
Here, the dimensionless height (h'/ H) is the distance (height): h'from the lower end of the furnace top bunker (height position of the raw material discharge port) to the top of the structure in the vertical direction. , Height of furnace top bunker: Value divided by H.
Further, the installation position of the structure is a position where the raw material falling from the raw material charging inlet collides with the raw material collision surface. The installation position of the structure is preferably such that the raw material falling from the raw material charging inlet inclines downward toward the end in the opposite direction of the eccentricity of the structure, and inclines downward toward the end in the first direction. A position that collides with at least one of the surface to be surfaced and a surface inclined downward toward the end in the second direction, more preferably, the raw material falling from the raw material charging inlet is simultaneously on these three surfaces. The position of collision (particularly, the position where the top of the structure is included in the collision range of the raw material falling from the raw material charging inlet).

Further, the above structure is preferably arranged so as to be symmetrical with respect to the vertical line passing through the center of the raw material storage portion when viewed from the eccentric direction, but the first direction from the top of the structure and It does not have to be symmetrical as long as it is inclined downward toward the end in the second direction.

In addition, the material of the above structure is not particularly limited, and a general steel material or the like may be used. Further, the method of installing the structure is not particularly limited. For example, a beam member is fixed to the inner wall of the furnace top bunker by metal fittings or welding, and the above structure is fixed to the beam member by metal fittings or welding. Just do it. Further, the above-mentioned structure may have a position adjusting mechanism for changing the position and an installation angle adjusting mechanism for changing the installation angle.

[Blast furnace raw material charging method]
The method for charging raw materials for a blast furnace according to an embodiment of the present invention is performed in a blast furnace in which one or more blast furnace top bunker according to the above-described embodiment of the present invention is arranged at the top of the furnace.
A process of charging raw materials from the raw material inlet of the furnace top bunker, colliding the raw materials with the above structure, and then storing the raw materials in the raw material storage section of the furnace top bunker.
It is equipped with a process of discharging the raw material stored in the raw material storage section of the furnace top bunker and charging the discharged raw material into the blast furnace via the swivel chute of the blast furnace.

First, in the process of storing the raw material in the raw material storage section of the furnace top bunker, the raw material charged from the raw material charging inlet is made to collide with the structure having the above shape, and the drop position of the raw material is set near the side wall opposite to the eccentricity. Not only the first wall portion and the vicinity of the second wall portion are also dispersed.
As a result, the shape of the raw material deposit layer in the furnace top bunker is inclined downward in the vertical direction toward the raw material discharge b not only from the side wall opposite to the eccentricity but also from the first wall portion and the second wall portion. In other words, the shape of the raw material deposit layer is roughly mortar-shaped. As a result, large particle size raw materials can be collected more closely near the raw material discharge port.

After the raw material is stored in the raw material storage section of the furnace top bunker in this way, the raw material is discharged, and the discharged raw material is charged into the blast furnace via a swivel chute.
As described above, in the furnace top bunker, the large particle size raw materials are more densely collected near the raw material discharge port, that is, more large particle size raw materials are discharged at the initial stage of raw material discharge from the furnace top bunker. .. Therefore, in the case of reverse tilt charging, the large particle size raw material is arranged closer to the vicinity of the center of the blast furnace. As a result, the gas flow rate near the center of the blast furnace is increased, and the air permeability and reduction efficiency are improved.

When the reverse tilting charge and the forward tilting charge are combined for each batch, for example, a position adjustment mechanism and an installation angle adjustment mechanism are separately provided in the structure, whereby the installation position and the installation angle of the structure are provided. By temporarily changing the above, the raw material drop position in the furnace top bunker may be adjusted so as to be near the center position of the furnace top bunker or the raw material discharge port. Further, at least one of the furnace top bunker arranged at the top of the furnace may be the top bunker according to the above-described embodiment of the present invention, and the rest may be the top bunker without the above structure. ..

Further, the conditions other than the above are not particularly limited, and the conventional method may be followed.

According to the following conditions 1 and 2, when the top bunker is modeled and the raw material is charged inside each top bunker, the distribution of the grain size of the raw material in the top bunker and the discharge of the raw material from the top bunker. The raw material discharge order (discharge time for each raw material storage position in the furnace top bunker) at the time was calculated by the discrete element method.
-Condition 1 (invention example)
[Shape of structure installed in the furnace top bunker]
Conical tilt angle: α = 42 °, β = 42 °, γ = 42 °
Width: a = R × 0.5, Length: b = R × 0.5, Height: h = a × 0.5
[Installation position of the structure in the furnace top bunker]
Position of the top of the structure: Position of r / R = 0.53 in the eccentric direction from the center position of the raw material storage part Installation height of the top of the structure: h'/ H = 0.82
・ Condition 2 (comparative example)
[Shape of structure installed in the furnace top bunker]
Plate-shaped (segregation control plate referred to in Patent Document 1),
Tilt angle: α = 25 °, β = 0 °, γ = 0 °,
Width: R x 0.31, Length: R x 1.0, Thickness: 160 mm
[Installation position of the structure in the furnace top bunker]
Center position of segregation control plate: Position of r / R = 0.37 in the eccentric direction from the center position of the raw material storage section Installation height of the center position of the segregation control plate: h'/ H = 0.42
Further, both the structures of conditions 1 and 2 were arranged so as to be symmetrical with respect to the vertical line passing through the center of the raw material storage portion when viewed from the eccentric direction.
Furthermore, regarding the shapes of the raw material storage section, raw material inlet, and raw material discharge port of the furnace top bunker, the same conditions as conditions 1 and 2 (R = 2350 mm, H = 12000 mm, raw material storage section and raw material discharge port are used according to the actual machine. Modeling was performed with the center-to-center distance (eccentricity): A = R × 0.64, and the inner radius of the raw material discharge port: B = R × 0.35).

In addition, the raw material charging conditions were the same for conditions 1 and 2. Specifically, the raw material here refers to ore, and the amount of raw material charged is equivalent to one batch. In addition, the particle size is represented by three types of large particles, medium particles, and small particles from the particle size distribution of the actual raw material, and the particle size ratio of large particles, medium particles, and small particles is 3.8 according to the actual raw material. : 2.0: 1.0. Furthermore, it was assumed that large particles, medium particles, and small particles each contained the same mass. At this time, the coke used the same bunker under conditions 1 and 2, respectively, and the charging conditions were also the same.
The evaluation results are shown in FIG.

As shown in FIG. 13, under the condition 1 (invention example), the large particles are collected more densely in the vicinity of the raw material discharge port as compared with the condition 2 (comparative example), and more large particles are collected at the initial stage of discharge. It turns out that it can be discharged.

Further, the raw materials in the blast furnace when the raw materials are charged into the blast furnace by reverse tilting charging using the deposited raw materials in the furnace top bunker of each of the condition 1 (invention example) and the condition 2 (comparative example). The distribution state and the pressure loss at the top of the furnace during blast furnace operation were obtained by numerical simulation.
The results are shown in FIGS. 14 and 15. In FIG. 14, the horizontal axis is the dimensionless radius of the blast furnace opening (value obtained by dividing the radial distance from the axis of the blast furnace opening by the inner radius of the blast furnace opening), and the vertical axis. The axis is the dimensionless particle size (radius of dimensionlessization of the blast furnace mouth: 0.05 pitch, and the average particle size of the raw material particles existing in each pitch region is the average of all the raw materials charged per batch. Value divided by particle size).

As shown in FIG. 14, under condition 1 (invention example), more large particles are arranged near the center of the blast furnace as compared with condition 2 (comparative example).
Further, as shown in FIG. 15, under condition 1 (invention example), the pressure loss at the top of the furnace is significantly improved as compared with condition 2 (comparative example).

It should be noted that even when the shape of the structure is variously changed in the range of α = 25 to 45 °, β = 25 to 45 °, and γ = 25 to 45 ° based on the condition of Condition 1 (invention example). Almost the same results as in Condition 1 (Example of the invention) were obtained. Further, even when the position of the top of the structure was variously changed in the range of r / R = 0 to 0.6, almost the same result as in Condition 1 (Example of the invention) was obtained. Further, when the shape of the structure is another shape such as the oblique cone shape or the elliptical cone shape described above, almost the same result as that of the condition 1 (invention example) was obtained. When the structure is not inclined downward from the top of the structure toward the eccentric direction, the position of the top of the structure is r / R = 0 to 1 in the eccentric direction from the center position of the raw material storage portion. Any position of .0 may be used, and the range of r / R = 0 to 0.6 is preferable in the direction opposite to the eccentricity.

In addition, a model experiment was conducted to confirm the accuracy of the particle size distribution in the furnace top bunker by the above numerical simulation.
That is, as shown in FIG. 16, a furnace top bunker model of an actual machine 1 / 17.8 size corresponding to the condition 1 (invention example) and the condition 2 (comparative example) was manufactured. In the figure, reference numeral 10 is a charging belt conveyor, 11 is a furnace top bunker model, 12 is a collective hopper model, 13 is a sampling box, 14 is a roller conveyor, and 15 is a sampling box belt conveyor.
Then, the raw material (here, ore) was charged into the furnace top bunker model from the charging belt conveyor. After charging, the valve of the discharge port connected to the lower end of the furnace top bunker model was opened, and the raw material was discharged from the discharge port. Then, the discharged raw materials were collected in a plurality of sampling boxes. At that time, the sampling box was gradually moved in the horizontal direction by the belt conveyor for the sampling box, and the discharged raw materials were sorted in chronological order at regular intervals from the start of discharge to the end of discharge. Then, the raw materials collected in each sampling box are screened, the average particle size of the raw materials collected in each sampling box is calculated, and the average particle size of all the raw materials before being charged into the furnace top bunker model is used. By dividing, the dimensionless particle size of the raw material was calculated for each dimensionless discharge time. The results are plotted in FIG. 17 with the horizontal axis representing the dimensionless discharge time and the vertical axis representing the dimensionless particle size.

From FIG. 17, it can be seen that condition 1 (invention example) can discharge more large particles at the initial stage of discharge than condition 2 (comparative example). That is, even in the model experiment, data supporting the above numerical simulation results were obtained.

1: Blast furnace 2: Tubular 3: Ore layer 4: Coke layer 5: Fused layer 6: Furnace top bunker 6-1: Raw material storage 6-2: Raw material discharge port 6-3: Segregation control plate 6-4: Structure 6-5: Raw material collision surface 6-6: Dispersion adjustment plate 7: Flow adjustment gate 8: Collective hopper 9: Swing chute 10: Charge belt conveyor 11: Furnace top bunker model 12: Collective hopper model 13: Sampling box 14: Roller conveyor 15: Belt conveyor for sampling box

Claims (5)

A furnace top bunker located at the top of a blast furnace.
The furnace top bunker
Raw material storage section and
A raw material charging inlet for charging raw materials into the raw material storage section from above the raw material storage section,
A structure which is arranged inside the raw material storage portion and has a raw material collision surface on which raw materials charged from the raw material charging inlet collide with each other.
A raw material discharge port that discharges the raw material in the raw material storage unit below the raw material storage unit, and
With
The raw material discharge port is arranged eccentrically from the center of the raw material storage portion on a horizontal plane.
Further, the raw material colliding surface of the structure is at least in the direction opposite to the eccentricity, and in the first direction and the second direction perpendicular to the opposite direction of the eccentricity and the vertical direction, respectively, from the top of the structure to the raw material. A furnace top bunker that slopes downward toward the end of the collision surface.
Here, the direction opposite to the eccentricity is the direction opposite to the direction in which the raw material discharge port is eccentric from the center of the raw material storage portion on the horizontal plane. The furnace top bunker according to claim 1, wherein the tilt angle α from the horizontal direction of the line segment connecting the top of the structure and the end of the raw material collision surface in the direction opposite to the eccentricity is 25 to 45 °. The horizontal inclination angles β and γ of the line segment connecting the top of the structure and the end of the raw material collision surface in the first direction and the second direction are 25 to 45 °, respectively. The furnace top bunker according to claim 1 or 2. The furnace top according to any one of claims 1 to 3, wherein the top of the structure is located in the range of 0 to 0.6 in a dimensionless distance (r / R) from the center of the raw material storage portion in a horizontal plane. bunker.
Here, the dimensionless distance (r / R) is a value obtained by dividing the distance (r) from the center of the raw material storage portion in the horizontal plane by the inner radius (R) of the raw material storage portion. It is a method of charging raw materials for a blast furnace.
The blast furnace has one or more top bunker according to any one of claims 1 to 4 at the top of the furnace.
In addition, the method of charging raw materials for the blast furnace is
A step of charging a raw material into the raw material storage unit from the raw material charging port of the furnace top bunker, causing the raw material to collide with the structure, and then storing the raw material in the raw material storage unit.
It is provided with a step of discharging the raw material stored in the raw material storage unit from the raw material discharge port and charging the discharged raw material into the blast furnace via the swirling chute of the blast furnace.
How to charge raw materials for blast furnace.

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