KR20120130035A - Apparatus for cooling sintered ore - Google Patents

Abstract

PURPOSE: A sintered ore cooling apparatus is provided to improve the utilization rate of cooling air for cooling sintered ore by using a sloping plate. CONSTITUTION: A sintered ore cooling apparatus comprises a body(100) formed in a closed loop shape with an air channel(AC), a charge port, and a discharge port, wherein cooling air passes through the air channel and sintered ore(SI) is inserted and discharged through the charge and discharge ports; carriages(200) which travel along the body from the charge port through the discharge port and back to the charge port and have through holes(230) connected to the air channel; a cooling air supply unit which is connected to the air channel to supply cooling air to the air channel; and a sloping plate(400) which is located inside the air channel, facing the through holes.

Description

Sintered ore cooling unit {APPARATUS FOR COOLING SINTERED ORE}

The present invention relates to a sintered ore cooling device, and more particularly, to a sintered ore cooling device for cooling the sintered ore using cooling air.

The sintered ore cooling device is an apparatus for cooling a sintered ore manufactured in a sintering machine having a high temperature of approximately 700 ° C to 900 ° C.

A conventional sintered ore cooling apparatus is disclosed in Korean Patent No. 10-0543511, which uses a cooling air as a cooling means for cooling the sintered ore.

One embodiment of the present invention is to provide a sintered ore cooling device that the utilization rate of the cooling air for cooling the sintered ore is improved.

One aspect of the present invention for achieving the above-described technical problem, in the sintered ore cooling device, forming an air passage through which cooling air passes, the charging hole is inserted into the sintered ore and spaced apart from the charging hole is discharged the sintered ore A closed loop-shaped body including a discharge port, which is movable from the charging hole through the discharge hole and back to the charging hole along the body from above the body, and through-holes formed to communicate with the air passage. It provides a sintered ore cooling apparatus including a bogie, a cooling air supply unit communicating with the air passage, and supplying the cooling air to the air passage, and an inclined plate disposed in the air passage and facing the through hole.

The inclined plate extends along at least one portion of the body, and a distance between the surface of the inclined plate and the body is the farthest from the first portion of the body adjacent to the cooling air supply. The second part may be narrowed sequentially.

The second portion may be closer to the charging hole than the first portion.

According to one embodiment of the above-described problem solving means of the present invention, there is provided a sintered ore cooling device in which the utilization rate of cooling air for cooling the sintered ore is improved.

1 is a plan view showing a sintered ore cooling apparatus according to an embodiment of the present invention.
2 is a sectional view taken along the line II-II in Fig.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art may easily implement the present invention. The present invention may be embodied in many different forms and is not limited to the embodiments described herein.

In order to clearly illustrate the present invention, parts not related to the description are omitted, and the same or similar components are denoted by the same reference numerals throughout the specification.

Also, throughout the specification, when an element is referred to as "including" an element, it is understood that the element may include other elements as well, without departing from the other elements unless specifically stated otherwise.

Hereinafter, a sintered ore cooling apparatus according to an embodiment of the present invention will be described with reference to FIGS. 1 and 2.

1 is a plan view showing a sintered ore cooling apparatus according to an embodiment of the present invention. 2 is a sectional view taken along the line II-II in Fig.

1 and 2, the sintered ore cooling apparatus according to an embodiment of the present invention is a device for cooling the sintered ore (SI) by using the cooling air (CA) as a cooling means, the body 100, bogie ( 200, a cooling air supply unit 300, and an inclined plate 400.

Body 100 has a closed loop (planar closed loop) form in plan, the cart 200 is supported to be movable along the body (100). Body 100 includes an inlet 110 and outlet 120. The charging hole 110 is formed at one side of the body 100, and is a portion into which the sintered ore SI is charged into the body 100 from the outside. Discharge port 120 is formed on the other side of the body 100, the sintered ore (SI) is a portion that is discharged from the body 100 to the outside. The sintered ore SI charged through the charging hole 110 is loaded on the trolley 200, and the sintered ore SI loaded on the trolley 200 is discharged to the outside through the outlet 120. The lower side of the body 100 is formed with an air passage (AC) through which the cooling air (CA) supplied from the cooling air supply unit 300, the cooling air (CA) through the air passage (AC) is the body 100 Is moved along. The air passage AC may be formed in a closed form except for the body 100 side, or may be formed in an open form, and may be formed in any form as long as the cooling air CA passes through. Body 100 includes a rail (rail), the trolley 200 is supported.

The trolley 200 is supported on the upper side of the body 100, and passes through the outlet 120 in the first direction from the charging port 110 along a rail formed in the body 100, and the charging port 110 again. It is possible to move to. The trolley 200 includes a loading part 210, a bottom part 220, and a through hole 230. The loading unit 210 has a box shape forming a predetermined space, and the sintered ore SI charged through the charging hole 110 is loaded in the predetermined space. The bottom part 220 is supported by the loading part 210 so as to be open to the loading part 210, and is opened when the truck 200 passes the outlet 120. The bottom portion 220 includes a wheel supported by a rail formed on the body 100, and the wheel is guided to the rail so that the bogie 200 moves along the body 100. The bottom portion 220 and the loading portion 210 may be coupled using a hinge (hinge). The through hole 230 is formed through the bottom portion 220 to communicate with the air passage (AC), the cooling air (CA) moved through the air passage (AC) along the body 100 is through the through hole (230) Cooling the sintered ore (SI) loaded on the balance 200 while passing through the balance 200 is discharged to the outside. On the other hand, the through hole 230 may be formed through the mounting portion 210, in this case, the cooling air (CA) moved through the air passage (AC) along the body 100 is the bottom portion 220 and loading The sintered ore SI loaded on the trolley 200 may be cooled through the unit 210.

The cooling air supply unit 300 communicates with an air passage AC formed along the body 100 and supplies cooling air CA to the air passage AC. The cooling air CA supplied from the cooling air supply unit 300 is discharged to the outside through the through hole 230 of the bogie 200 while moving the air passage AC along the body 100. Sintered ore SI mounted on the trolley | bogie 200 is cooled by this cooling air CA.

The inclined plate 400 shown in FIG. 2 is located in the air passage AC to face the through hole 230 of the trolley 200 and extends along at least a portion of the body 100. Here, at least one portion of the body 100 means a portion of the body 100 or the whole of the body 100. In detail, the inclined plate 400 is the second portion 102 of the body 100 farthest from the first portion 101 from the first portion 101 of the body 100 neighboring the cooling air supply 300. It extends along the body 100 to. The distance L between the surface of the inclined plate 400 and the body 100 is sequentially narrowed from the first portion 101 to the second portion 102 of the body 100, in the form of such an inclined plate 400. As a result, the utilization rate of the cooling air CA for cooling the sintered ore SI loaded on the trolley 200 is improved, and the cooling efficiency of the overall sintered ore cooling device is improved. In particular, the second part 102 of the body 100 is located closer to the charging inlet 110 than the first part 101, which firstly reveals that it takes into account the structure of the overall sintered ore cooling device.

Hereinafter, the utilization rate of cooling air CA by the inclination plate 400 is demonstrated in detail.

When the inclined plate 400 is not present in the air passage AC through which the cooling air CA passes, the cooling air CA supplied from the cooling air supply unit 300 to the air passage AC is connected to the body through the air passage AC. While moving along the 100, only a part of the entire cooling air CA moves in the direction of the trolley 200 to cool the sintered ore SI. That is, the cooling air CA supplied from the cooling air supply unit 300 to the air passage AC has a substantially horizontal orientation, so that most of the entire cooling air CA passes through the air passage AC and only a part of the cooling air CA passes through the air passage AC. Since the sintered ore SI mounted on the trolley 200 is cooled by moving in the direction of the trolley 200 located above the air passage AC, the utilization rate of the cooling air CA is not large.

On the other hand, in the sintered ore cooling apparatus according to an embodiment of the present invention, the inclined plate 400 facing the through hole 230 of the bogie 200 is positioned in the air passage AC, thereby providing horizontal directionality from the cooling air supply unit 300. Since the cooling air CA supplied to the air passage AC is guided in the direction of the trolley 200 by the inclination plate 400 and moves in the direction of the trolley 200 with the vertical direction, the entire cooling air CA is The utilization rate of the cooling air CA is improved by moving in the direction of the through hole 230 of the trolley 200 located above the air passage AC to cool the sintered ore SI loaded on the trolley 200. This improves the overall cooling efficiency of the sintered ore cooling device according to an embodiment of the present invention.

Furthermore, the sintered ore SI initially supplied from the outside to the sintered ore cooling device through the charging inlet 110 has a high temperature of 700 ° C. to 900 ° C. In consideration of the structure of the overall sintered ore cooling device, the inclined plate 400 is cooled air. Of the body 100 which is farthest from the first part 101 of the body 100, which is adjacent to the supply part 300, and is closer to the charging inlet 110 than the first part 101. Extending along the body 100 to the second portion 102, the distance L between the surface of the inclined plate 400 and the body 100 is from the first portion 101 of the body 100 to the second portion 102. ) To narrow sequentially. As a result, the space formed by the air passage AC gradually decreases from the first portion 101 to the second portion 102 of the body 100 so that the cooling air CA supplied in the direction of the trolley 200 may be reduced. Since the air volume and the wind speed increase from the first portion 101 to the second portion 102 of the body 100, more cooling is performed on the sintered ore SI loaded on the trolley 200 through the charging hole 110. Cooling of the sintered ore SI carried out first in this second portion 102 and loaded in the trolley 200 is performed more efficiently.

As such, the sintered ore cooling apparatus according to the embodiment of the present invention simply cools the sintered ore SI loaded on the trolley 200 by simply placing the inclined plate 400 in the air passage AC through which the cooling air CA passes. Since the entire cooling air CA to be used is used for cooling the sintered ore SI, the utilization rate of the cooling air CA is improved, and the cooling efficiency with respect to the sintered ore SI is improved.

While the invention has been shown and described with reference to certain preferred embodiments thereof, it will be understood by those skilled in the art that various changes and modifications may be made therein without departing from the spirit and scope of the following claims. Those who are engaged in the technology field will understand easily.

Air passage (AC), body 100, bogie 200, cooling air supply unit 300, inclined plate 400

Claims (3)

In the sintered ore cooling device,
A closed loop-shaped body including an air inlet through which cooling air passes and a charging inlet through which a sintered ore is charged and an outlet through which the sintered ore is discharged from the charging inlet;
A bogie including a through hole formed in the upper side of the body and movable from the charging hole through the discharge port to the charging hole and passing through the air passage and communicating with the air passage;
A cooling air supply unit communicating with the air passage and supplying the cooling air to the air passage; And
An inclined plate positioned in the air passage and facing the through hole
Sintered ore cooling device comprising a. In claim 1,
The inclined plate extends along at least one portion of the body,
And a distance between the surface of the inclined plate and the body is sequentially narrowed from a first portion of the body adjacent to the cooling air supply to a second portion of the body farthest from the first portion. In claim 2,
And said second portion is closer to said charging opening than said first portion.

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