KR102105427B1 - Screw-type direct reduced iron cooling system - Google Patents

Abstract

The present invention relates to a screw-type direct reduction iron method cooling device, and the material introduced in the process of producing high-grade ore iron through a direct reduction iron process is heated at a high temperature in an electric furnace and then produced. In the cooling device for cooling the, the hopper portion receiving the processed material supplied after high-temperature heating, the transfer screw for transferring the material supplied through the hopper portion to go through the cooling process, rotating the transfer screw at a constant speed Screw rotation means, a cooling water supply device for spraying cooling water to the surface of the delivery screw to cool the high-grade iron conveyed through the delivery screw, to accelerate the cooling rate by exhausting hot heat generated from the delivery screw surface to the outside Cooling fan provided for supplying cooling gas into the delivery screw It comprises a cooling gas supply device for cooling the material.

Description

Screw-type direct reduced iron cooling system

The present invention relates to a screw-type DRI cooling device, and more specifically, to stabilize the transformation state of the material by rapidly cooling the DRI material maintained at a high temperature through a processing step in a direct reduction iron process. It relates to a screw-type DRI cooling device that can be maintained.

The method of manufacturing iron is roughly divided into a blast furnace ironing method using relatively low-grade general iron ore having a quality of about 60%, and a direct reducing ironing method using iron ore having a high-quality iron quality of 68% or more. The direct reduction steelmaking method is a method of producing iron sources (reduced iron) by reducing iron ore by using high-grade concentrates with a reducing gas such as carbon monoxide and hydrogen, and then melting the reduced iron in an electric furnace to produce high-purity, high-quality molten metal.

On the other hand, steel production using electric furnaces mainly uses scrap metal and waste scrap as raw materials. Since electric furnaces have a shorter initial investment and equipment construction period compared to blast furnaces, the introduction of electric furnace facilities has been increasing mainly in emerging industrial countries.

However, supply of scrap metal and waste scrap is not stable, and labor costs and technical problems for removing impurities from low-grade scrap metal have been caused.

Despite the increase in the introduction of electric furnace production facilities, the stable supply of scrap metal and waste scrap has become difficult, and through the direct reduction steelmaking method using electric furnaces to cope with the demand for steel in emerging and emerging countries. Steel manufacturing is on the rise.

As a raw material of direct reduced iron, iron ores such as hematite and magnetite, which are naturally produced, are used, and strict quality requirements are required for iron quality and particle size. That is, in order to satisfy the raw material condition of direct reduced iron, the iron quality is 68% or more and impurity elements should hardly be mixed, and the particle size can pass through a 200 mesh sieve having a sieve of 0.075mm or more by 80% or more. It should have a particle size distribution.

Iron ore produced in nature, even if it is a high-grade ore, has an iron quality of about 60% and is calculated as a mass, so to use it directly as a raw material for reduced iron, it is necessary to undergo a crushing process and a screening process to improve iron quality. However, there is a problem in that the existing process of making raw materials with iron quality of 68% or more from iron ore is economical. Particularly, prior to beneficiation, a group separation process of crushing and crushing iron ore into fine particles should be preceded, and this process was the biggest cause of inefficiency.

Accordingly, it is necessary to develop an economical method of selectively recovering only iron ore step by step from the iron ore using the mineralogical difference between iron ore and impurity.

KR 10-1607255 KR 10-1587199 KR 10-1714931 KR 10-1638447

The present invention for solving the above problems, as one of the process of the process that can recover the iron ore processed in a direct reduction iron method at a high speed, excellent and efficient quenching and cooling of the heat-treated material is physically stable and high quality The aim is to provide a DRI high-speed cooling device capable of producing light.

Accordingly, an object of the present invention is to provide a high-quality direct reduction iron method with high economic efficiency.

The present invention for achieving the above object, the direct reduction iron method (direct reduction iron) through the process of producing high-grade ore iron in the process of high-temperature heating in an electric furnace, and then through the process of producing the material to cool the material In the cooling device for, the hopper portion receiving the processed material supplied after high-temperature heating, the transfer screw for transferring the material supplied through the hopper portion to go through the cooling process, screw rotating means for rotating the transfer screw at a constant speed , Cooling water supply device for spraying cooling water to the surface of the delivery screw to cool the high-quality iron transferred through the delivery screw, is provided to accelerate the cooling rate by exhausting the hot heat generated from the delivery screw surface to the outside Cooling the material by supplying cooling gas into the cooling fan and the delivery screw That it is configured to include a cooling gas feeder.

In addition, the transfer screw is a screw having a cylindrical structure, and the transfer ribs are configured at regular intervals on the inner circumferential surface to transfer the material during rotation.

In addition, the transfer rib includes a transfer rib for transferring the material forward when the transfer screw rotates, and a mixing rib for mixing the material according to the rotation.

In addition, the mixing ribs are arranged at predetermined intervals along the intervals in which the preliminary feed ribs are arranged, and the angle of the feed ribs is controlled according to the speed control of the transfer screw to control the feed speed of the cooled material.

In addition, the coolant supply device is configured to have a length corresponding to the length of the transfer screw to supply coolant to the entire surface of the transfer screw that rotates, and the coolant supply device controls the injection amount according to the rotational speed of the transfer screw.

In addition, the rotating means, the rollers rotating while surrounding the outer surface of the transfer screw are provided on each side, and rotated by receiving the power of the drive motor from one side to rotate the transfer screw through the drive of the roller.

In addition, the cooling fan, a chamber surrounding the transfer screw is further provided and is installed on the chamber and configured to exhaust the temperature of the transfer screw located in the chamber to the outside.

The present invention configured and operated as described above has an effect of providing a cooling device for preventing high-temperature molding DRI oxidation in order to prevent oxidation of iron ore raw materials discharged from the direct reduction iron process.

The screw-type direct reduction iron method cooling apparatus according to the present invention is a method for rapidly cooling the material in order to prevent the oxidation of the material in the employee reduction iron method process, and includes a three-step process including cooling water cooling, wind cooling, and reducing gas supply. By cooling through, there is an advantage that the cooling efficiency for pellet raw materialization can be satisfied.

1 is a schematic configuration diagram of a screw-type direct reduction iron method according to the present invention,
Figure 2 is a schematic configuration diagram of a screw-type direct reduction iron cooling system according to the present invention,
Figure 3 is a side cross-sectional view of a screw-type direct reduction iron cooling system according to the present invention,
Figure 4 is a front view showing the transfer screw of the screw-type direct reduction iron cooling system according to the present invention,
5 is an exploded view of the transfer screw of the screw-type direct reduction iron cooling system according to the present invention.

Hereinafter, a preferred embodiment of a screw type DRI cooling device according to the present invention will be described in detail with reference to the accompanying drawings.

The screw-type DRI cooling apparatus according to the present invention cools the material through a process of heating and then heating the input material in a high-temperature furnace in a process of producing high-grade ore iron through a direct reduction iron process. In the cooling device for, the hopper portion receiving the processed material supplied after high-temperature heating, the transfer screw for transferring the material supplied through the hopper portion to go through the cooling process, screw rotating means for rotating the transfer screw at a constant speed , Cooling water supply device for spraying cooling water to the surface of the delivery screw to cool the high-quality iron transferred through the delivery screw, is provided to accelerate the cooling rate by exhausting the hot heat generated from the delivery screw surface to the outside Cooling the material by supplying cooling gas into the cooling fan and the transfer screw Key is configured to include a cooling gas feeder.

The screw-type direct reduction iron cooling apparatus cooling apparatus according to the present invention is used to rapidly cool the pelletized material molded at high temperature in the direct reduction iron process to prevent the oxidation and stabilize the material. The step cooling process is performed. The cooling process using a cooling water using the cooling water supply device 400 and a cooling fan 500 for cooling the surface temperature of the transfer screw being moved while the material is cooled, and inert gas into the screw. It comprises a cooling gas supply to prevent oxidation by supplying and cooling the material.

1 is an overall configuration diagram of a screw-type direct reduction iron method according to the present invention. The screw type direct reduction iron method cooling apparatus according to the present invention rapidly prevents oxidation by rapidly cooling the pelletized material heated in an electric furnace in a method for producing high purity iron having an iron quality of 68% or more in steel production. There is a great purpose to construct a DRI cooling device for this.

Looking at the schematic configuration of FIG. 1 to configure the DRI cooling device, an electric furnace 10 for melting high-quality iron in an electric furnace process and a cooling device 100 for rapidly cooling the material of the pellet structure discharged therefrom It is configured, and the present invention aims to prevent oxidation by producing high-quality pelletized high-quality iron at a high speed, and to produce an excellent level of iron material. .

2 is a schematic configuration diagram of a screw-type direct reduction iron method cooling apparatus according to the present invention, and FIG. 3 is a side cross-sectional view of a screw-type direct reduction iron method cooling apparatus according to the present invention.

As shown in the drawing, the cooling device is largely composed of a transmission screw 300, a cooling water supply device 400, a cooling fan 500, and a cooling gas supply device 600.

As mentioned above, when the pelletized iron material discharged from the electric furnace is discharged at a high temperature, it must undergo a very efficient quenching process to stabilize the temperature to stabilize the physical properties of the material. In particular, since high-quality iron materials in a high temperature state can easily cause oxidation, it is necessary to cool the materials under optimized quenching conditions.

To this end, the present invention proposes a cooling device capable of rapidly cooling through a three-step process, and has an inner circumferential surface that is geometrically configured to discharge heat of the material transferred through the transfer screw. This will be explained in more detail below.

The transfer screw 300 has a hollow cylindrical shape and a transfer rib 310 and a mixing rib 320 are provided to transfer the material into the hollow interior. The transfer screw is operated to move the material forward while rotating, and at this time, rotates through the rotating means 330. Although the rotating means 330 is not shown in detail, a motor for supplying power is provided, and rollers supported to be rotatable on both sides of the transmission screw are provided so that the material injected therein is transferred while the transmission screw rotates by power transmission. .

Here, the material of the transfer rib 310 is provided at a predetermined angle so that the material is transferred, and the mixing rib 320 is stirred to allow the heat to be quickly discharged.

When the material is transferred through the transfer screw, the coolant is rapidly cooled by spraying coolant through the transfer screw through the coolant supply device 400 to the outer surface of the transfer screw. The cooling water supply device receives cooling water from the outside and provides an injection nozzle corresponding to the length of the transfer screw so that cooling water can be sprayed over the entire surface of the rotating screw.

As described above, there is an advantage in that the material can be rapidly cooled by cooling by spraying cooling water on the surface of the transfer screw by the cooling water supply device.

In addition, the present invention includes a cooling means using a cooling fan for faster cooling control. Cooling fan 500 is further described as a means for exhausting heat generated from the transfer screw to the outside. The transfer screw described above is located in a separate chamber (not shown) and the heat generated by the transfer screw surface is the cooling fan. It is discharged to the outside through (500).

The cooling fan is preferably composed of a plurality of cooling fans, is installed on the chamber surface is configured to exhaust the internal heat to the outside.

The direct reduction iron method to be carried out in the present invention is a process for producing high-grade ore iron, and it is very important to prevent oxidation of the material. Therefore, in the present invention, a supply device 600 for supplying cooling gas is provided so that cooling efficiency can be generated while supplying an inert gas directly to a material transported through a transfer screw for rapid cooling and oxidation prevention. That is, it is possible to achieve very stable cooling by supplying gas so that the inert gas can be supplied to the inside of the delivery screw.

4 is a front view showing the transfer screw of the screw-type direct reduction iron method cooling apparatus according to the present invention, and FIG. 5 is an exploded view of the transfer screw of a screw-type direct reduction iron method cooling apparatus according to the present invention.

As mentioned above, the transfer screw according to the present invention is characterized by controlling the flow of the material so that the cooling devices can cool the high temperature material quickly while transporting the material well. In order to achieve this, a transfer rib 310 and a mixing rib 320 are formed inside the transfer screw of the cylindrical structure, and fixedly installed at predetermined intervals to take charge of material transfer and mixing rib 320 ), Because it stirs the hot material, it is possible to control the heat to be quickly discharged.

The present invention configured as described above is provided with a transfer screw capable of transferring the material at a high speed to cool the DRI (direct reduction iron method) material at a high speed and a complex cooling means capable of supplying cooling water and cooling gas thereto. In addition, it has the advantage of stabilizing the material at a rapid rate by having a cooling mechanism to achieve a physically rapid cooling rate.

As described above, although it has been described and illustrated in connection with a preferred embodiment for illustrating the principles of the present invention, the present invention is not limited to the configuration and operation as illustrated and described. Rather, those skilled in the art will appreciate that many changes and modifications to the present invention are possible without departing from the spirit and scope of the appended claims. Accordingly, all such suitable changes and modifications and equivalents should be considered to be within the scope of the present invention.

100: cooling device
200: hopper
300: transfer screw
310: Transfer rib
320: mixing rib
330: rotating means
400: cooling water supply
500: cooling fan
600: cooling gas supply device

Claims (7)

In the cooling device for cooling the material after the high-temperature heating in an electric furnace in the process of producing high-grade ore iron through a direct reduction iron process and then producing the material,
A hopper part receiving the processed material supplied after high temperature heating;
A transfer screw for transferring the material supplied through the hopper to undergo a cooling process;
Screw rotation means for rotating the transmission screw at a constant speed;
A cooling water supply device that sprays cooling water onto the surface of the delivery screw to cool high-grade iron transferred through the delivery screw;
A cooling fan provided to accelerate the cooling speed by exhausting the hot heat generated from the transfer screw surface to the outside; And
And a cooling gas supply device for cooling a material by supplying a cooling gas into the delivery screw,
The transfer screw is a screw having a cylindrical structure, the transfer ribs are formed at regular intervals on the inner circumferential surface to transfer the material during rotation,
The transfer screw comprises a transfer rib for transferring the material forward when the transfer screw rotates, and a mixing rib for mixing the material according to the rotation,
Mixing ribs are arranged at predetermined intervals along the intervals in which the transfer ribs are arranged, and the angle of the transfer ribs is controlled according to the speed control of the transfer screw to control the transfer speed of the cooled material,
The cooling water supply device is configured to have a length corresponding to the length of the transmission screw to supply cooling water to the entire surface of the rotating transmission screw, and the cooling water supply device is a screw type direct reduction iron method that controls the injection amount according to the rotational speed of the transmission screw. Cooling system. delete delete delete delete According to claim 1, The rotating means,
A roller that rotates while surrounding the outer surface of the transfer screw is provided on both sides, and receives the power of a drive motor from one side to rotate the transfer screw through the drive of the roller, thereby rotating the screw-type direct reduction iron cooling system. . According to claim 1, The cooling fan,
A screw-type direct reduction iron cooling system configured to further exhaust the heat of the transfer screw located in the chamber, the chamber surrounding the transfer screw is further provided and installed on the chamber.

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