KR101436597B1 - Cooling apparatus - Google Patents

Abstract

The present invention relates to a cooling apparatus that includes a plurality of cars, which contains a raw material therein, moves along the moving pathway, and passes air entering from a lower side thereof to cool the raw material. The cart includes a lower plate which supports the raw material and includes a main vent hole formed therein; and a protection plate arranged on a portion where the cart and another cart arranged close to the cart are joined. A subsidiary plate on which a subsidiary vent hole is formed is arranged above the protection plate. A flow channel through which air flows is formed by an upper side of the lower plate, an upper part of the protection plate, and a lower side of the subsidiary plate. An inlet communicating with the flow channel is formed on the lower plate, arranged between the protection plate and the subsidiary plate. The cooling apparatus can efficiently cool a high-temperature raw material such as sintered ore.

Description

[0001]

The present invention relates to a cooling apparatus, and more particularly, to a cooling apparatus capable of efficiently cooling an sintered orbit.

The sintered ores used as raw materials in the blast furnace are produced by mixing iron ore and coal, burning coal, and sintering the iron ore with the heat of combustion. At this time, the temperature of the sintered ores, which are sintered and discharged from the sintered bogie, are subjected to a cooling process of cooling to 100 ° C or less in order to transport the sintered ores to a belt conveyor at a high temperature of about 800 to 1000 ° C.

FIG. 1 is a schematic view of a general sinter orbital manufacturing facility, FIG. 2 is a view showing a cooling device of the sinter orbital manufacturing facility shown in FIG. 1, FIG. 3 is a perspective view showing an inner bottom structure of the car shown in FIG. And Fig. 4 is a view showing the temperature measurement result of the sintered ores.

In general, as shown in FIG. 1, in a general sintered-crystal manufacturing process, an appropriate amount of a large amount of various raw materials and subsidiary raw materials stored in a raw material reservoir (not shown) is extracted by a basis weight belt (not shown) ) Is mixed with moisture and then transported to the surge hopper 14 by a belt conveyor (not shown) and temporarily stored.

Thereafter, the upper raw material stored in the upper light hopper 12 and the raw material mixture stored in the surge hopper 14 are loaded on the sintered bogie 18 and transported. The sintered bogie 18 containing the raw material is transported to the ignition furnace 16, It is ignited at the upper part of the raw material mixture due to the coke which is a subordinate raw material passing through the lower part. The sintered bogie 18 carrying the ignited raw material proceeds to the side of the crusher 20. The suction air volume of the main blower 19 at this time is supplied to the sintered bogie 18 through the wind box 17 installed in the lower portion of the sintering machine 10. [ ) Of the mixed ingredients. When the sintered bogie 18 is almost reached the direction of the crusher 20 due to the intake air volume of the main blower 19, when the blended raw material on the sintered bogie 18 is sintered to the lower portion and is shined to the crusher 20 The light-distribution sintered ores are crushed to a predetermined size or less and then loaded on the cooling device 30 and cooled.

2, the cooling device 30 includes a plurality of bogies 32 on a circular body 31 having a bow inlet (not shown) for receiving sintered light and a light emitting portion (not shown) for emitting sintered light. And a guide rail 36 for guiding the carriage 32 is provided on the upper surface of the body 31. A carriage 32 is rotatably mounted on the lower side of the carriage 32 along the guide rail 36, And a bogie wheel 33 for guiding the movement of the bogie wheel. A cooling fan (not shown) is installed on the side surface of the body 31 to supply air for cooling the sintered light to the inside of the body.

3, a bottom plate 37 having a plurality of air holes 37a for supporting sintered light and passing air supplied to the inside of the body 31 by a cooling fan is provided at the bottom of the bogie 32 do. Shafts 34 are provided on both sides of the bogie 32 to interconnect the bogie wheels 33 provided on the side of the bogie 32. [ The shaft 34 may be provided with a central adjustment device 35 such as a ball bearing or the like for adjusting the center of the bogie 32. Since the central adjusting device 35 such as the shaft 34 and the ball bearing is vulnerable to heat, a protection plate 38 for blocking radiant heat from the sintered light in the bogie 32 may be provided on the upper part thereof. The protection plate 38 is provided between the lower plate 37 of the bogie 32 and the lower plate of the bogie adjacent to the bogie 32 and extends in the direction intersecting the moving direction of the bogie 32, So as to protrude upward.

The plurality of bogies 32 thus formed are formed so that the inside thereof is communicated with each other, so that the sintered light is evenly distributed over the plurality of bogies 32. 4, the sintered light of the region C in which the lower plate 37 is provided is efficiently cooled by the air supplied by the cooling fan, whereas the region H where the protection plate 38 is provided, The sintered ores are kept at a high temperature even after the cooling is completed because the supply of air is cut off. As a result, there is a problem that a belt conveyer for conveying the sintered light that has been cooled or a screen for sorting the sintered ores are damaged by the high-temperature sintered light.

KR 2011-34371 A KR 543511 B KR 658290 B

The present invention provides a cooling device capable of efficiently cooling a raw material at a high temperature to improve productivity.

The present invention provides a cooling device capable of suppressing damage to facilities and improving lifetime.

A cooling apparatus according to an embodiment of the present invention includes a plurality of bogies that accommodate a raw material therein and move along a movement path and pass air introduced from a lower portion to cool the raw material, And a protection plate disposed at a connection portion between the bogie and the bogie disposed adjacent to the bogie, wherein the auxiliary plate is provided with an auxiliary vent hole And a flow passage through which the air moves is formed by the upper surface of the lower plate, the upper surface of the protection plate, and the lower surface of the auxiliary plate, and a gap between the protection plate and the auxiliary plate And an inlet port communicating with the flow path is formed in the lower plate disposed in the lower plate. The.

The protection plate and the auxiliary plate may be arranged to be in contact with each other at least partially.

The auxiliary vent hole may be formed such that the side where the air is discharged is inclined downward.

The upper surface of the lower plate to which the auxiliary plate is contacted is formed with an insertion groove along the width direction of the lower plate, and both ends of the auxiliary plate can be inserted into the insertion groove.

The cooling apparatus according to the embodiment of the present invention can efficiently cool sintered high-temperature light. That is, a flow path and a vent hole through which air flows into the upper part of the truck, which blocks air in a truck accommodating a high-temperature sintered light, are formed to uniformly cool the high-temperature sintered light accommodated in the truck. Therefore, it is possible to suppress or prevent damage to the equipment such as a conveyor belt for conveying the sintered ore and a screen for sorting.

Further, by improving the cooling efficiency of the sintered ores, the productivity of the sintered ores can be improved.

BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 is a schematic view of a general sintering plant; Fig.
FIG. 2 is a view showing a cooling apparatus of the sintering apparatus shown in FIG. 1. FIG.
3 is a perspective view and a cross-sectional view showing the inner floor structure of the bogie shown in Fig. 2;
4 is a view showing a result of temperature measurement of the sintered ores.
5 shows a cooling device according to an embodiment of the invention.
6 is a perspective view showing an inner bottom structure of the bogie shown in Fig. 5;
7 is a cross-sectional view showing an inner bottom structure of the bogie shown in Fig. 6;

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. It will be apparent to those skilled in the art that the present invention may be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete, It is provided to let you know.

5 is a perspective view showing the internal floor structure of the bogie shown in Fig. 5, Fig. 7 is a view showing the internal bottom structure of the bogie shown in Fig. 6, and Fig. Sectional view.

Referring to FIG. 5, the cooling apparatus includes a plurality of bogies 300 mounted on an upper portion of a circular body having an intestinal inlet (not shown) for receiving sintered light and a light shading portion (not shown) for emitting sintered light, A guide rail 36 for guiding the carriage 300 is installed on the upper surface of the carriage 300. A carriage wheel 33 for guiding the carriage 300 to move along the guide rail is installed below the side of the carriage 300 . In addition, a cooling fan (not shown) for supplying air for cooling the sintered ore to the inside of the body is installed on the side surface of the body. Such a cooling device may be formed in a structure substantially similar to that of the conventional cooling device shown in Fig. 2, except for a part of the internal structure of the carriage 300. [

The carriage 300 includes sidewalls forming a space for storing sintered light therein, and a lower plate 310 and a carriage wheel 33 supporting the sintered light. A protective plate 330 is provided between the carriage 300 and the carriage 300 to contact the end of the lower plate 310. An auxiliary plate 320 is disposed on the upper portion of the protection plate 330 to form a communication path 340 between the protection plate 330 and the protection plate 330.

The lower plate 310 is formed with a plurality of main ventilation holes 312 through which air flows. At this time, the main vent hole 312 may be formed up to a region adjacent to the protection plate 330 in order to suppress the damage of the shaft 34 and the center adjuster 35 connecting the truck wheel 33. The lower plate 310 is rotatably connected to the carriage 300 at one side thereof and is connected to be movable in the vertical direction with respect to the moving direction of the carriage 300. When the bogie 300 is positioned at the light-shading portion, the other side of the lower plate 310 may be moved downward to discharge the sintered light in the bogie 300.

The protection plate 330 is provided on the upper side of the shaft 34 interconnecting the moving wheels 33 and is disposed on the upper surface 310 of the lower plate 310 in order to suppress the influence of the high temperature sintered light, As shown in FIG. Although the center of the protection plate 330, that is, the position at which the shaft 34 is disposed, is shown as being protruded in a triangular shape, it may be curved and protruded.

At this time, the protection plate 330 is provided with a shaft 34 for interconnecting the wheel 33 and a center adjustment device 35 such as a ball bearing provided on the shaft 34 to protect the center adjustment device 35 from radiant heat emitted from the sintered ores As compared with the lower plate 310 in which the vent holes are formed, ventilation holes are not formed. Therefore, the sintered light accommodated in the region where the protection plate 330 is provided is difficult to be brought into contact with air, so that cooling is not smoothly performed.

Therefore, in the embodiment of the present invention, air is supplied to a region where the protection plate 330 is disposed, so that the sintered light charged on the bogie 300 can be uniformly cooled.

That is, the auxiliary plate 320 having the plurality of auxiliary ventilation holes 322 formed on the protection plate 330 is spaced apart from the protection plate 330 so that the upper surface of the protection plate 330 and the lower surface of the auxiliary plate 320 And a flow path 340 into which air flows is formed. At this time, the auxiliary vent hole 322 formed in the auxiliary plate 320 is formed such that the air is inclined downward to about 40 to 50 degrees so that the auxiliary vent hole 322 is clogged by the sintered light accommodated in the car 300 Can be prevented. An inlet 314 is formed in an edge area of the lower plate 310 so that air flows into the flow path 340 so that the air supplied from the cooling fan flows into the flow path 340 through the inlet 314, 320 through the auxiliary vent holes 322 of the sintered ores.

6, the cross-sectional shape of the auxiliary plate 320 may be a triangular shape in which the upper side of the shaft 34 is most protruded, for example, Or the like.

The auxiliary plate 320 may be disposed so as to be wholly spaced from the protection plate 330 as shown in FIG. 7a), and may be configured to be in contact with at least a portion of the protection plate 330 as shown in FIG. 7b) . In the former case, there is a risk that the auxiliary plate 320 is deformed by the load of the sintered light received in the bogie 300. In the latter case, the auxiliary plate 320 is supported by the protection plate 330, There is an advantage that the shape can be stably maintained.

Both lower edges of the auxiliary plate 320 may be connected to the edge region of the lower plate 310. [ At this time, since the lower plate 310 is vertically moved to discharge the cooled sintered light in the light pipe, an insertion groove 316 having a predetermined depth is formed at a portion connected to the lower edge of the auxiliary plate 320 So that the lower edge of the auxiliary plate 320 is inserted into the insertion groove 316. With this configuration, it is possible to prevent the air flowing into the flow path 340 formed by the plate, the protection plate 330 and the lower plate 310 from flowing out to the connection portion between the auxiliary plate 320 and the lower plate 310 So that the flow rate of air discharged to the auxiliary vent hole 322 can be increased. The flow path 340 is formed between the upper surface of the protection plate 330 and the lower surface of the auxiliary plate 320 and more specifically between the upper surface and the lower surface of the auxiliary plate 320. [ And may be formed through the upper edge region of the face and lower plate 310.

A plurality of inlets (not shown) passing through the lower plate 310 in the vertical direction are provided between the protection plate 330 and the auxiliary plate 320 in order to introduce air through the flow path 340. (314) may be formed.

The inlet 314 passes air supplied from the cooling fan and flows into the flow path 340. At this time, the inlet 314 may be the same size as the main vent hole 312 formed in the lower plate 310 or may be formed to be smaller than the main vent hole 312. The air flowing into the flow path 340 is supplied to the sintered light accommodated in the carriage 300 through the auxiliary vent hole 322 formed in the auxiliary plate 320 to cool the sintered light.

With this structure, the sintered light accommodated in the bogie 300 can be efficiently cooled without a dead zone, and the damage of equipment for sorting and transporting the subsequent sintered ores can be suppressed or prevented. In addition, it is possible to effectively prevent the radiant heat emitted from the sintered ores from being transmitted to the shaft 34 and the center adjuster 35 in the process of cooling the sintered ores.

Here, the cooling device is described as being applied to cool a high-temperature sintered ore, but it can be applied to cooling various raw materials at a high temperature.

Although the present invention has been described in connection with certain exemplary embodiments, it is to be understood that the invention is not limited to the disclosed exemplary embodiments. Therefore, the scope of the present invention should not be limited by the described embodiments, but should be defined by the appended claims and equivalents thereof.

30: cooling device 33: truck wheel
34: shaft 35: center adjustment device
300: Cart 310: Lower plate
320: auxiliary plate 330: protective plate

Claims (4)

1. A cooling device comprising a plurality of bogies for receiving a raw material therein, moving along a moving path, and passing air introduced from a lower portion thereof to cool the raw material,
The bogie comprises:
A lower plate supporting the raw material therein and having a main vent hole,
And a protection plate disposed at a connection portion between the bogie and a bogie disposed adjacent to the bogie,
An auxiliary plate having an auxiliary vent hole formed therein is disposed at an upper portion of the protection plate and a flow path is formed through an upper surface of the lower plate and an upper surface of the protection plate and a lower surface of the auxiliary plate,
And an inflow port communicating with the flow path is formed in the lower plate disposed between the protection plate and the auxiliary plate. The method according to claim 1,
Wherein the protection plate and the auxiliary plate are arranged to be at least partially in contact with each other. The method according to claim 1 or 2,
Wherein the auxiliary vent hole is formed such that the side from which air is discharged is inclined downward. The method according to claim 1 or 2,
An insertion groove is formed on an upper surface of the lower plate to which the auxiliary plate is contacted along a width direction of the lower plate,
And both ends of the auxiliary plate are inserted into the insertion groove.

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