KR101630994B1 - Apparatus for cooling sintered ore and method for cooling sintered ore - Google Patents

Abstract

The present invention relates to an apparatus to cool sintered ore used as a raw material to manufacture steel, and a cooling method thereof. The present invention is to provide the apparatus and the method to cool the sintered ore, which improves sintered ore cooling efficiency through local air volume control and ventilation control. According to one aspect of the present invention, provided are the apparatus to cool the sintered ore, comprising: more than two temperature measurement units to measure sintered ore temperature at more than two spots in a width direction of the sintered ore by being stacked on a trolley; an air volume control unit configured to control air volume to supply more air to a spot with a higher temperature measured by the temperature measurement unit than a spot with a lower temperature by controlling the volume of wind transferred through a wind transfer path; and a ventilation control unit which adjusts ventilation of the sintered ore by forming more than one valley in a transfer direction of the sintered ore, in the high temperature sintered ore stacked on the trolley on a front of the air volume control unit, as seen in a transfer direction of the sintered ore, and the sintered ore cooling method using the same. According to the present invention, the apparatus to cool the sintered ore is able to prevent a facility from degradation of a belt by being able to improve a cooling efficiency of the sintered ore, and has also the effect of being able to improve a quality of the sintered ore as it is not necessary to perform water cooling.

Description

FIELD OF THE INVENTION [0001] The present invention relates to a cooling apparatus for cooling a sintered ores,

The present invention relates to a sintered-crystal cooling device and a cooling method for cooling sintered ores used as a raw material for a steelmaking process, and more particularly to a sintered-crystal cooling device and a cooling method capable of improving the cooling efficiency of sintered- will be.

The sintered ores used as the raw materials for the seasoning are usually prepared by charging iron ores and additives to a sintering machine and sintering them at a high temperature.

1, the sintered ores are sintered at a high temperature of about 700 to 800 ° C. and are discharged onto a truck 10 of the cooling apparatus 100. The sintered ores are stacked on the truck 10, (1) is cooled to about 80 DEG C or lower for about 40 to 50 minutes.

That is, in the cooling device 100, the cooling of the sintered light 1 is carried out by the wind transfer means 30 such as a fan to transfer the wind to the lower portion of the truck where the sintered light is stacked through the wind transfer path 20 This wind passes through the laminate and the sintered-stratum laminate layer in this order, so that the sintering of the high-temperature sintered light is cooled.

But. When the sintered light of high temperature is laminated on the cooling device, segregation occurs in the sintered light laminated layer, and the cooling efficiency is lowered because the air does not pass through the region having poor air permeability. do.

If the temperature of the sintered ores discharged from the cooling device is 100 ° C or higher, the equipment such as a belt conveyor provided at the rear end of the cooling device is damaged. If this is severe, the equipment is stopped And the like.

Generally, in the case of the summer season, there arises a further problem of cooling efficiency of the sintered ores. If the cooling is not sufficient due to the airflow control, water is usually sprayed with water.

However, water-cooling the sintered ores causes undesirable breakage of the sintered ores, leading to a decrease in the strength of the sintered ores and an increase in the fraction.

Further, when water is sprayed to the sintered ores of high temperature, the dust duct is clogged, which causes a problem of generation of scattered dust.

Further, there is a problem that a blowing occurs due to a failure of the rubber seal at the lower end of the cooling device.

It is an object of the present invention to provide a sintered orbit cooling apparatus and a cooling method capable of improving sintered-light cooling efficiency through local airflow control and airflow control.

According to an aspect of the present invention, there is provided a sintering machine comprising: a saddle-struck high-temperature sintered body produced by stacking and transporting sintered ores; And a wind transfer means for transferring the wind from the lower portion of the truck to the upper portion through the wind transfer path to cool the high temperature sintered light to be stacked and transported on the truck, Two or more temperature measuring devices for measuring the temperature of the sintered ores at two or more points in the direction of the temperature; An air flow rate control means configured to control an amount of wind to be delivered through the wind transmission path and to control the air flow rate so that a larger amount of wind is supplied to a point higher than a temperature point measured by the temperature measuring device; And air permeability control means capable of adjusting the air permeability of the sintered ores by forming at least one sphere in the sintered light transport direction in the high temperature sintered compact laminated on the bogie.

According to another aspect of the present invention, there is provided a sintering machine comprising: a sludge sintering machine for sintering high temperature sintered organs produced by the sintering machine; and a windward conveying passage And a wind transfer means for transferring the wind from the lower portion of the truck to the upper portion through the wind transfer passage to cool the high temperature sintered light that is stacked and transported on the truck, Measuring the temperature of the sintered ores at two or more points in the width direction of the sintered light to be stacked and transported on the bogie, and controlling the airflow so that a larger amount of wind is supplied at a point higher than the measured temperature; And controlling the air permeability of the sintered ores by forming one or more valleys in the sintered light transport direction in the high temperature sintered compact which is stacked and transported on the bogie.

According to the present invention, it is possible to improve the cooling efficiency of the sintered light, thereby preventing deterioration of the equipment such as a belt, and in addition, it is not necessary to perform water cooling, thereby improving the quality of the sintered ores.

1 is a schematic view showing an example of a conventional sintered-crystal cooling apparatus.
2 is a graph showing a difference in cooling temperature depending on the sintered-light confluence (the conveying speed: 2.5 m / s) and the granularity (the conveying speed: 0.1 m / s).
Fig. 3 is a schematic view showing an example of air flow rate control means of the sintered orbit cooling apparatus according to the present invention. Fig.
4 is a schematic view showing an example of the air flow control means of the sintered-crystal cooling apparatus according to the present invention.
5 is a graph showing changes in the opening ratio of the damper according to the temperature of the sintered ores.

Hereinafter, an example of a sintered-crystal cooling apparatus according to the present invention will be described in detail with reference to the drawings.

In the case where the sintered light of high temperature is cooled by using the conventional sintered light cooling apparatus as shown in Fig. 1, segregation occurs in the sintered light laminated layer stacked on the bed of the cooling apparatus, And it is maintained at 100 DEG C or higher even when it is discharged from the cooling device.

For example, when segregation occurs in the sintered light laminated layer on the above-mentioned bank, as shown in Fig. 2, the cooling rate of the small sintered light compared to that of the opposite sintered light is remarkably reduced. In Fig. 2, the graph of the conveying speed of 2.5 m / s shows the temperature of the homogeneous sintered ores having a diameter of 5 mm or more, and the graph showing the conveying speed of 0.1 m / s shows the temperature of the sintered ores of the small pores having a diameter of 5 mm or less. Since the cooling rate of the small sintered ores is slower than that of the opposite sintered ores, the transporting speed of the small sintered light on the bogie should be made slower than the transport speed of the opposite sintered ores.

2, when the temperature of the sintered ores is compared with that after 40 minutes of cooling, the temperature of the sintered ores is 100 ° C, but the temperature of the sintered ores is 350 ° C because the temperature of the sintered ores is high.

In order to solve the above problems, the inventor of the present invention has found that, in order to solve the above problems, the width direction of the cooling device, for example, the width direction temperature of the sintered light which is stacked on the bogie and transported is measured to locally control the amount of air in the lower part of the cooling device An sintered-light cooling apparatus and a sintered-light cooling method capable of controlling the air permeability of the sintered ornaceous light to be stacked and transferred.

As shown in FIG. 3, an example sintered light cooling apparatus 200 according to the present invention stacks and transports high temperature sintered light 1 manufactured in a sintering machine (not shown), winds up and down A wind transfer passage 20 connected in a wind connection relationship with the lower portion of the bogie, and wind transfer means for transferring wind from the lower portion of the bogie to the upper portion through the wind transfer passage 20 30).

The wind transfer means 30 may be, for example, a fan.

The sintered-crystal cooling apparatus 200 includes at least two temperature measuring devices 40 for measuring the temperature of sintered light, air volume control means 50 configured to control the amount of wind to be transferred through the wind transfer path 20, And air permeability control means 60 for adjusting the air permeability of the sintered ores.

The temperature measuring device 40 is not particularly limited and may be of any type as long as it is commonly used. The temperature measuring device 40 can be used as the temperature measuring device 40, Can be measured.

The air flow rate control means 50 may be configured to control the air flow rate so that a larger amount of wind is supplied to a point higher than the point where the temperature measured by the temperature measuring device 40 is lower.

The air flow rate control means 50 may be any of those capable of adjusting the flow rate in the width direction of the vehicle, and a plurality of air flow rate control means 50 may be used.

The air flow rate control means 50 may be a damper 501 and the damper 501 may be plural.

When the air volume control means 50 is a damper, the air volume can be controlled by controlling the opening ratio of the damper.

For example, by increasing the opening ratio of the damper corresponding to the point where the temperature is higher than the opening rate of the damper corresponding to the point at which the temperature measured by the temperature measuring device 40 is higher, The air flow rate can be controlled so that the airflow of the airflow is supplied.

The ventilation control means 60 is configured to form one or more valleys in the conveying direction of the sintered light to the high-temperature sintered light laminated on the carriage as shown in Figs. 3 and 4. Fig.

The ventilation control means 60 may preferably be installed in front of the airflow control means when viewed in the conveying direction of the sintered light.

The air-permeable control means 60 may be any type as long as it can form one or more valleys in the direction of transport of the sintered light. For example, the air-permeable control means 60 may be a vertical plate disposed perpendicularly to the upper surface of the tank, Is more than one.

The vertical plate may be provided so as to be movable up and down, and the height of the vertical plate may be controlled according to particle size, temperature, etc. of the sintered light stacked on the bed.

For example, it is possible to form deeper and / or wider bones in a region higher than the region where the temperature of the sinter is lower. Further, it is possible to form deeper and / or wider bones in a region having a smaller grain size than a region having a larger grain size of sintered ores.

3 and 4 show an example of the ventilation control means 60 structured to be able to move in a cylinder manner.

One example of the ventilation control means 60 configured to be able to move in the cylinder manner is a support member 601, a cylinder 602 supported by the support member 601, And a vertical plate 603 that forms a sphere in the sintered ores.

The air-permeable control means 60 is not limited to the air-permeable control means configured to be able to move in a cylinder manner, but may be, for example, an air-permeable control means configured to be movable in a rack- Air permeability control means and the like can be used.

An example of the sintered light cooling apparatus according to the present invention may include a controller 70 configured to control the air flow rate control means 50 according to the widthwise temperature value of the sintered ore measured from the temperature measuring device 40 have.

The controller 70 may adjust the breathability control means 60 as shown in Figs.

Hereinafter, an example of a method of cooling a sintered or high-temperature light according to the present invention will be described.

As shown in FIGS. 3 and 4, an example of the present invention includes a truck 10 stacked and transported at a high temperature sintered light produced in a sintering machine, the truck 10 being configured to allow wind to pass upward and downward, And a wind transfer means (30) for transferring the wind from the lower portion of the car to the upper portion through the wind transfer passage (20) connected to the upper portion of the car, The sintered light cooling apparatus 200 for cooling the sintered ores is used to cool the high temperature sintered ores.

Preferably at least three points in the width direction of the sintered ores by using a temperature measuring device 40 or the like provided at two or more, preferably three or more points in the width direction of the sintered light to be laminated on the above- Is measured.

The air flow rate is controlled using the air flow rate control means 50 or the like so that a larger amount of air is supplied to a point higher than the low temperature point by using the temperature value measured as described above.

The air volume control by the air volume control means 50 can be performed by, for example, controlling the opening ratio of the damper when the air volume control means 40 is a damper.

For example, the air volume can be controlled by a method in which a damper provided at a position corresponding to a portion having an sintered light temperature of 400 DEG C or higher is opened 100%.

FIG. 5 shows changes in the opening ratio of the damper according to the sintering temperature when the sintered light is cooled using the sintered light cooling apparatus according to an example of the present invention.

As can be seen from Fig. 5, the air volume can be controlled in such a manner that the damper opening ratio at the position corresponding to the portion having a high sintering light temperature is made larger than the damper opening ratio at the position corresponding to the portion having a low sintering light temperature.

Preferably, the air volume control is performed using a controller 70 configured to control the air volume control means 50 according to the temperature value in the width direction of the sintered light measured by the temperature measuring device 40.

In the present invention, one or more valleys are formed in the sintered light transporting direction in the sintered high-temperature light which is stacked and transported on the bogie to control the air permeability of the sintered light.

The bone formation and bone depth control can be performed by moving the vertical plate 603 up and down by the ventilation control means 60 configured to be able to move in a cylinder manner, as shown in Fig.

The air flow control of the sintered ores may be performed prior to the air flow rate control step.

The one or more valleys may be formed by the ventilation control means 60, for example by one or more vertical plates.

The bone formation by the vertical plate is performed in a manner similar to a rake.

The depth and width of the sliver can be controlled according to the particle size, temperature, etc. of the sintered light deposited on the bogie.

For example, it is possible to form deeper and / or wider bones in a region higher than the region where the temperature of the sinter is lower. Further, it is possible to form deeper and / or wider bones in a region having a smaller grain size than a region having a larger grain size of sintered ores.

The air permeability control can be performed by controlling the air permeability control means 60 through the controller 70 as shown in Figs. 3 and 4.

1: Sintered ores
10: Bogies
200: Sintered light cooling device
20: wind transmission path
30: Wind transport means
40: Temperature meter
50: air volume control means
60: air permeability control means
601: Support member
602: Cylinder
603: Vertical plate
70:

Claims (12)

A bogie constructed to stack and transport the sintered ores produced in the sintering machine and configured to allow the wind to communicate with the upper and lower sides, a wind feed passage connected in a wind communication relationship with the lower portion of the bogie, An apparatus for cooling an sintered light which is stacked on and transported on a bogie including a wind transfer means for transferring wind to an upper portion of the bogie, Two or more temperature measuring devices; An air flow rate control means configured to control an amount of wind to be delivered through the wind transmission path and to control the air flow rate so that a larger amount of wind is supplied to a point higher than a temperature point measured by the temperature measuring device; And air permeability control means for adjusting the air permeability of the sintered light by forming at least one sphere in the sintered light transport direction in the sintered light stacked on the bogie, And the air flow rate control means is configured to be able to adjust the amount of wind (air volume) to be delivered through the wind transfer path in the width direction of the bogie.
delete delete 2. The sintered orbit cooling apparatus according to claim 1, wherein the airflow control means includes a plurality of dampers.
The sintered orbit cooling apparatus according to claim 4, wherein the air volume control of the air volume control means is performed by controlling the opening ratio of the damper.
2. The sintered orbit cooling apparatus according to claim 1, wherein the air permeability control means comprises at least one vertical plate disposed perpendicularly to the upper surface of the bed and forming a valley in the conveying direction of the sintered light.
2. The sintered orbit cooling apparatus according to claim 1, wherein the ventilation control means is a ventilation control means configured to be able to move in a cylinder manner.
The air conditioner according to any one of claims 1 and 4 to 7, wherein the air flow rate control means is controlled in accordance with the temperature value in the width direction of the sintered ore measured by the temperature measuring device, And a controller configured to control the sintered light cooling apparatus.
A bogie configured to stack and transport the sintered ores produced in the sintering machine and to allow the wind to communicate with the upper and lower portions; A wind transfer passage connected in a wind communication relationship with the lower portion of the bogie; Wind transfer means for transferring the wind from the lower portion of the truck to the upper portion through the wind transfer passage; Two or more temperature gauges for measuring the temperature of the sintered ores at two or more points in the width direction of the sintered ores that are stacked and transported on the bogie; And an air flow rate control means configured to control the amount of wind to be delivered through the wind transfer path and to control the air flow rate so that a larger amount of wind is supplied to a point higher than the point where the temperature measured by the temperature measuring device is higher A method of cooling an sintered light by using a sintered light cooling apparatus for cooling an sintered light to be stacked and transported on the truck, comprising the steps of: measuring the temperature of the sintered light at two or more points in the width direction of the sintered light, Controlling the air flow rate such that a larger amount of air is supplied to a point higher than the measured temperature; And controlling the air permeability of the sintered light by forming one or more valleys in the sintered light transport direction stacked and transported on the bogie, wherein the step of controlling the air permeability comprises the steps of: Cooling method.
delete 10. The method according to claim 9, wherein the air flow rate control means includes a damper, and the air flow rate control is performed by controlling the opening ratio of the damper.
The air conditioner according to claim 11, wherein the air flow control is performed by controlling the opening ratio of a plurality of dampers, and a damper provided at a position corresponding to a portion having an sintered light temperature of 400 ° C or higher is opened by 100% Characterized in that the sintered light cooling method comprises:

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