JP2011231381A - Method for treating agglomerated ore - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a method for treating an agglomerated ore which can be efficiently fed into a blast furnace without sticking particulate powder.SOLUTION: The method for treating the agglomerated ore is characterized by including: a washing step for washing the agglomerated ore with water; and a dehydration step for feeding the washed agglomerated ore into a centrifugal dehydration type dehydrating machine and removing the surface water. In addition, it is characterized in that the number of rotation of the centrifugal dehydration machine in the dehydration step is adjusted so that the gravity acceleration applied on the agglomerated ore becomes at least 400 m/sec. Furthermore, it is characterized in that a continuous centrifugal dehydration machine which continuously feeds the agglomerated ore into a rotating screen is used, and the number of rotation of the centrifugal dehydration machine in the dehydration step is adjusted so that the gravity acceleration applied on the agglomerated ore becomes at most 700 m/sec.

Description

  The present invention relates to a method for treating a lump ore used as a part of a main raw material for charging a blast furnace.

The lump ore used as a raw material in the blast furnace is adjusted to a predetermined particle size, for example, 6 mm to 30 mm, and then charged into the blast furnace.
Normally, fine powder (for example, powder of less than 6 mm) adheres to the surface of the lump ore just stacked in the yard, but if fine powder adheres, it is brought into the furnace. There is concern about adverse effects on furnace ventilation.
Therefore, it is necessary to remove such fine particles, but the fine particles containing moisture are strongly adhered to the surface of the lump ore due to the influence of rain and the like, so it is difficult to remove them by sieving, for example. .

Therefore, as a technique for removing fine particles adhering to the surface of the lump ore, Patent Document 1 proposes a method for washing the ore with water.
The ore water washing method proposed in Patent Document 1 is “recovering fine powder by washing the lump ore containing fine powder with a screen jet water washer and dewatering the wash water with a first screen dehydrator. Then, the discharged washing water from the first screen type dehydrator is supplied to the hydrocyclone to separate the fine powder, and then the separated fine powder is dehydrated by the second screen dehydrator. The ore water-washing method characterized in that the ore is recovered "(see claim 1 of Patent Document 1).

  Patent Document 2 proposes a technique of using a lump ore previously washed with water as a floor for a sintering machine (see claim 2 of Patent Document 2).

JP-A-7-113127 JP 2003-277840 A

Patent Document 1 describes washing the lump ore with water to remove the fine powder, and processing of the removed fine powder, but with regard to the subsequent treatment of the lump ore that has been washed and wetted with water. Not touched.
The lump ore is transported toward the furnace, but if the lump ore is transported in a wet state, moisture adheres to the conveyor surface of the belt conveyor and the inner wall of the blast furnace hopper during the transport process. Thus, it is conceivable that the fine powder pulverized in the conveying process adheres again to the surface of the lump ore. In addition, if the wet ore in a wet state is charged into the furnace as it is, moisture enters the furnace, so there is a concern that the top temperature of the blast furnace will decrease, and more fuel is required in the blast furnace. There is also a problem.

On the other hand, Patent Document 2 describes that wet ore is dried by heat by using the washed ore as a bed for a sintering machine.
However, drying the lump ore by using it as a floor for a sintering machine cannot be used for efficient loading of the lump ore into the furnace. In addition, there is a problem that the productivity of the sintering machine is lowered and the properties of the ore to be used are limited.

  This invention is made | formed in order to solve this subject, and it aims at providing the processing method of the lump ore which can be charged in a blast furnace efficiently without adhesion of fine powder.

The inventor examined how to remove the fine particles adhering to the lump ore and suppress the entry of moisture into the blast furnace as much as possible.
First, it was concluded that washing with water was effective in removing fine particles adhering to the lump ore piled up in the yard. However, if the water adhering to it by washing with water is not treated, as described above, there is a problem that the fine powder adheres again to the surface of the lump ore during the conveyance process by a belt conveyor or the like. In addition, since moisture enters the furnace, there is a concern that the top temperature of the blast furnace will decrease, and there is a problem that more fuel is required in the blast furnace.

Therefore, it is necessary to remove water from the lump ore washed with water, and a method generally considered as a method for removing water is to dry with hot air. In this respect, the method of Patent Document 2 is similar to this.
However, according to the inventor's study, for example, when drying is performed by applying hot air from below the laminated ore, it is possible to dry the lower part of the ore directly hitting the hot air, but it is in the upper layer It was found that the lump ore hits with hot air containing saturated steam, and is difficult to dry, resulting in poor efficiency. In other words, such a drying method leads to high costs and a problem of large CO ₂ emission.

When the condition of moisture adhering to the lump ore was confirmed, it was found that most of the moisture was adhering near the surface of the lump ore and the penetration into the inside was small. In addition, the significance of removing the moisture of the lump ore is prevention of adhesion of fine particles during the conveyance process and suppression of the penetration of moisture into the furnace. If this is the case, what is important for the removal of water from the massive ore is that there is no need for a method of drying the inside of the ore, and that the water adhering to the surface is effectively removed and no pulverization occurs.
Therefore, as a result of examining such a water removal method, considering that the water is separated from the lump ore using centrifugal force, an experiment was conducted, and the washed lump ore was put into a centrifugal dehydrator. The present inventors have obtained knowledge that surface adhering water can be effectively removed without causing pulverization.

  The present invention has been made on the basis of the above-described consideration and research, and specifically comprises the following configuration.

(1) The lump ore processing method according to the present invention includes a water washing step for washing the lump ore and a dehydration step for removing the surface water by introducing the washed lump ore into a centrifugal dehydration type dehydrator. It is characterized by.

(2) Further, in the above (1), the rotational speed of the centrifugal dehydrator in the dehydration step is adjusted so that the gravitational acceleration applied to the ore is 400 m / sec ² or more. It is.

(3) In addition, in the above-described (1) or (2), a continuous centrifugal dehydrator in which a lump ore is continuously added to a rotating screen is used, and the rotational speed of the centrifugal dehydrator in the dehydration step Is adjusted so that the gravitational acceleration applied to the ore is 700 m / sec ² or less.

  In the present invention, it is attached to the surface of the lump ore by providing a water washing step for washing the lump ore and a dehydration step for removing the surface water by putting the washed ore into a centrifugal dehydrator. The fine powder can be removed effectively, and the moisture adhering to the surface of the lump ore can be removed effectively without causing the lump ore to be pulverized. Ore can be obtained.

It is explanatory drawing of the process of the processing method of the lump ore in one embodiment of this invention. It is explanatory drawing of the structure of the centrifugal dehydrator used for the processing method of the lump ore in one embodiment of this invention. It is a graph which shows the relationship between the residual water content and the gravity acceleration in the Example of this invention. It is a graph which shows the relationship between the content rate of the fine powder of less than 6 mm in the Example of this invention, and gravity acceleration.

In the lump ore processing method according to the present embodiment, as shown in the explanatory diagram of the processing step in FIG. 1, a water washing step (S1) for washing the lump ore 3 to which the fine powder 1 of less than 6 mm is adhered and the water washing are performed. A dehydration step (S2) in which the lump ore 3 is put into a centrifugal dehydration type dehydrator to remove the surface water 5, and a lump ore 3 that has undergone the dehydration step is charged into a blast furnace.
Hereinafter, main steps will be described in detail.

<Washing process>
The water washing step is a step of removing the fine powder 1 of less than 6 mm attached to the surface of the lump ore 3 by water washing. The washing method is not particularly limited, and for example, a method in which high-pressure water is sprinkled on the lump ore 3 or a method in which the lump ore 3 is charged in a rotary drum type washing apparatus and washed with water may be used. Alternatively, a method of washing with a screen-type jet washing machine may be used.

<Dehydration process>
The dehydration step is a step of removing the surface water 5 by putting the lump ore 3 washed with water into a centrifugal dehydration type dehydrator.
The structure of the dehydrator is not particularly limited, and a known one can be used. For example, as shown in FIG. 2, <Factory Operation Series> Augmentation / Centrifuge Separation, Chemical Industry, June 1974 The vertical continuous centrifugal dehydrator 7 described in the first edition on the 15th, p.227 can be used.
A vertical continuous centrifugal dehydrator 7 shown in FIG. 2 includes a drive shaft 9 that is rotated by a motor (not shown), a basket 11 that is fixed to the drive shaft 9, and an inverted frustoconical screen mounted on the basket 11. 13 and a hopper 15 for charging the lump ore 3.
The lump ore 3 charged into the hopper 15 passes through the hopper 15 and is supplied to the screen surface that rotates at high speed. The lump ore 3 supplied to the screen surface is dewatered by receiving centrifugal force, gradually rises on the screen surface, falls from the upper edge of the screen surface to the solid discharge port 17 side, and is discharged. On the other hand, the dehydrated water passes through the screen 13 and is discharged from the liquid discharge port 19.

By using the continuous centrifugal dehydrator as described above, the moisture on the surface of the lump ore 3 can be efficiently dehydrated.
The continuous centrifugal dehydrator is not limited to the vertical type as shown in FIG. 2 and may be a horizontal centrifugal dehydrator in which the screen 13 is installed sideways.

The relationship between the moisture remaining in the lump ore 3 and the gravitational acceleration acting on the lump ore 3 when the lump ore 3 was dehydrated by a continuous centrifugal dehydrator was investigated by experiments.
The lump ore 3 used is a hematite ore A from which fine particles of less than 6 mm have been removed by washing with water, and a pisolite ore B that has also been washed with water. The hematite ore A is an ore having a small porosity and a relatively stickiness, and the pisolite ore B is a ore having a large porosity and a relatively brittleness.
The continuous centrifugal dehydrator used was a horizontal centrifugal dehydrator with a horizontal screen. The residence time of the iron ore in the apparatus was 1 to 4 seconds.

FIG. 3 is a graph showing the results of this experiment. The vertical axis represents the residual moisture content (mass%), and the horizontal axis represents the gravitational acceleration (m / sec ² ). As shown in the graph of FIG. 3, when the residual water content is ore A, the gravity acceleration is further increased by decreasing to about 6.0% by mass, and in the case of ore B to about 6.8% by mass. Even so, it was found that the amount of residual water remained almost constant without decreasing. The gravitational acceleration when the decrease in the residual water content stopped was about 400 m / sec ² . Therefore, from the viewpoint of reducing the residual moisture content, the gravitational acceleration is preferably 400 m / sec ² or more. However, even if the gravitational acceleration exceeds 400 m / sec ² , the effect of dehydration does not increase, so even if the gravitational acceleration is considerably increased from 400 m / sec ² , energy is wasted. For example, 1000 m / sec ² or less is preferable, and 700 m / sec ² or less or 500 m / sec ² or less is also preferable in order to eliminate waste of energy.

  When the appearances of the ores A and B after the dehydration treatment were examined, the surfaces of both the ores A and B were dry, and it was confirmed that the surface water 5 adhering to the ore surface could be removed according to the method of the present invention. As a result, it was proved that the problems of wetting the inner walls of the belt conveyor and the blast furnace hopper during ore transportation and the fine powder 1 adhering to the surface of the lump ore 3 were solved.

Even if the coarse ore 3 is washed with water and the fine powder 1 is removed, if the powder is generated in the dehydration process and the powder is generated, the effect is halved. Whether or not powder is generated when a continuous centrifugal dehydrator is used We also investigated. The lump ore 3 and the dehydrating apparatus used are the same as those in Example 1.
In the experiment, the gravitational acceleration applied to the ore was changed to confirm the state of pulverization.

FIG. 4 is a graph showing the results of this experiment, where the vertical axis represents the content ratio (mass%) of the fine powder 1 having a size of less than 6 mm, and the horizontal axis represents the gravitational acceleration (m / sec ² ).
As shown in the graph of FIG. 4, the powder that did not contain the fine powder 1 of less than 6 mm before the experiment was 1.4% by mass in the ore A after the experiment with the gravitational acceleration of 500 m / sec ^2. In B, it was 2.8 mass%. Moreover, after experimenting at a gravitational acceleration of 1000 m / sec ² , the ore A was 7.1% by mass and the ore B was 13.3% by mass. Furthermore, after experimenting at a gravitational acceleration of 3000 m / sec ² , the ore A was 18.0% by mass and the ore B was 32.0% by mass.
From this experiment, it was found that the content ratio of the fine powder 1 increases as the gravitational acceleration increases.
From the viewpoint of maintaining air permeability in the furnace, it is necessary to make the content ratio of the fine powder 1 less than 5% by mass. Therefore, the gravitational acceleration for making the content ratio of the fine powder 1 less than 5% by mass is illustrated. It is 700 m / sec ² or less when read from the graph of 4.
Therefore, in order to reduce the pulverization of the lump ore 3 to less than 5% by mass, the gravitational acceleration needs to be set to 700 m / sec ² or less.

The inventor investigated the cause of the increase in the pulverization of the lump ore 3 when the gravitational acceleration increases. It has been found that the main cause is the occurrence of crushing in the lump ore 3 when.
Therefore, in a continuous centrifugal dehydrator of the type in which the lump ore 3 is continuously charged into the screen 13 that rotates at a high speed from the inlet, the gravitational acceleration is set to reduce the lump of the lump ore 3 to less than 5% by mass. 700 m / sec ² or less is preferable, but a means for suppressing pulverization due to contact between the lump ore 3 and the screen 13 at the time of charging, or a lump ore 3 is used. The gravitational acceleration need not necessarily be 700 m / sec ² or less if powdering at the time of charging is prevented.

DESCRIPTION OF SYMBOLS 1 Fine powder 3 Lump ore 5 Surface water 7 Vertical continuous centrifugal dehydrator 9 Drive shaft 11 Basket 13 Screen 15 Hopper 17 Solid discharge port 19 Liquid discharge port

Claims (3)

  A lump ore processing method comprising: a water washing step for washing lump ore; and a dewatering step for removing the surface water by feeding the washed lump ore into a centrifugal dehydrator. ^2. The lump ore processing method according to claim 1, wherein the rotational speed of the centrifugal dehydrator in the dewatering step is adjusted so that a gravitational acceleration applied to the ore is 400 m / sec ² or more. Using a continuous centrifugal dehydrator that continuously feeds the ore to the rotating screen, and adjusting the rotational speed of the centrifugal dehydrator in the dehydration process so that the gravitational acceleration applied to the ore is 700 m / sec ² or less. The processing method of the lump ore of Claim 1 or 2 characterized by these.