KR100908708B1 - Coke dry quenching of bucket - Google Patents

Abstract

A coke bucket of dry quenching facility is provided to prevent explosion accident by burning unburned cokes before inserted to the dry quenching facility. A coke bucket of dry quenching facility comprises a bucket(10) loading cokes in the internal space with one side open, and one or more air guides(70) provided on the outer surface of the bucket. The bucket has an air hole on the part in which the air guides are combined so that the outside air flows into the bucket through the inlet of the air guide and the air hole when the bucket rotates.

Description

{COKE DRY QUENCHING OF BUCKET}

The present invention relates to a dry fire extinguishing facility, and more particularly to a dry fire extinguishing facility coke bucket.

In the dry fire extinguishing system, when the heat coke is charged into the main body in the unburned state, hydrogen may rise in the circulating gas and may explode. Explosion may occur during charging by charging the bucket cover during winding, or by circulating gas in the system after charging.

However, in order to prevent such an explosion accident, when the unburned portion is generated during the extrusion, the driver suspends the operation of the hoisting crane temporarily, waits for a certain time, checks the flame in the bucket, and if the unburned portion is incinerated, And charging was carried out. That is, the driver confirmed that the unburned fraction was charged, and at the same time, the supply amount of the combustion air of the dry fire extinguishing apparatus main body was increased, and the charging was carried out in a state of lowering the hydrogen concentration in the system.

In the case of using the above method, if the supply amount of the combustion air is suddenly increased, a large amount of combustion occurs suddenly in the main body of the dry fire extinguishing system, so that the temperature of the boiler inlet suddenly rises. Therefore, all of these work methods must be performed by the driver in advance. If you can not take action, you can see that the unburned fraction is charged only after checking the hydrogen concentration after the unburned fraction is charged. Therefore, there is a problem that causes an explosion accident accordingly.

The present invention provides a dry fire extinguishing facility coke bucket capable of minimizing the concentration of hydrogen in a coke oven by charging unburned fraction in the course of being loaded in a dry fire extinguishing system bucket after extrusion, even when unburned coal is extruded from the coke oven.

A coke bucket of a dry fire extinguishing system comprises a bucket for loading coke in an internal space with one side open and at least one opening formed in the outer surface of the bucket and having an inlet for guiding the outside air of the bucket to the inside of the bucket when the bucket rotates Wherein the bucket has an air hole at a portion where the air guide is engaged and the air hole is formed such that when the bucket rotates, the outside air of the bucket flows into the inside of the bucket through the inlet of the air guide and the air hole And the air is introduced into the bucket through the air holes to burn out the poorly heated red coke while extruding.

The air guide may protrude from the outer surface of the bucket and have an inlet formed with a predetermined inclination and inclined toward the direction in which the bucket rotates.

The angle at which the inlet of the air guide is tilted can be about 25 degrees to 35 degrees.

And an air inlet opening / closing member coupled to the air guide.

The air inlet opening and closing member is connected to the inlet of the air guide and includes a damper for opening and closing the inlet of the air guide according to external force, a damper shaft for supporting the damper, a damper weight for closing the damper by interlocking with gravity, A damper weight bracket for combining the damper and the damper weight, and a damper weight rod for connecting the damper weight and the damper weight bracket.

The glow coke extruded from the coke oven is extruded in a state in which it is partially incompletely burned and burned in the extruding process before being charged into the dry fire extinguishing system main body. In this state, since the concentration of hydrogen generated in unsteady flow is minimized, it is charged into the dry fire extinguishing apparatus main body, so that stable operation and explosion accident of the dry fire extinguishing apparatus can be prevented in advance.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings, which will be readily apparent to those skilled in the art to which the present invention pertains. The present invention may be embodied in many different forms and is not limited to the embodiments described below. In the specification and drawings, the same reference numerals denote the same elements.

FIG. 1 is a view showing a coke bucket of a dry fire extinguishing system according to an embodiment of the present invention, and FIG. 2 is a partial cross-sectional view schematically showing a state where outside air is introduced into a bucket through an air guide.

The coke bucket of the dry fire extinguishing system according to the embodiment of the present invention includes a bucket 10, an air guide 70. In an embodiment of the present invention, an air guide (70) is coupled to a bucket (10) which is loaded through a dry fire extinguishing facility main entrance and is loaded with a red coke to be pressed in a coke oven of a dry fire extinguishing facility, Even if the coke is extruded, the unburned fraction can be burned in the bucket 10 during extrusion.

The bucket 10 loads the coke in the inner space where one side is opened. A cover (12) is coupled to the open portion of the bucket (10). The bucket 10 is formed in a structure in which a plurality of liners are coupled to the frame, and the air guide 70 can be formed substantially on the liner. However, the detailed structure of the bucket 10 is omitted in the description of the embodiment of the present invention, and therefore, it is described that the air guide 70 is coupled to the bucket 10. The bucket 10 has an air hole 100 at a portion where the air guide 70 is engaged. The air hole 100 is a passage through which the outside air of the bucket 10 flows into the bucket 10 through the inlet of the air guide 70 and the air hole 100 when the bucket 10 rotates. And air is introduced into the bucket 10 through the air hole 100 to burn out the poorly heated red coke while extruding it.

At least one air guide 70 is formed on the outer surface of the bucket 10 and has an inlet for guiding the outside air of the bucket 10 into the bucket 10 when the bucket 10 rotates. The air guides 70 may be coupled in the appropriate number in the bucket 10 and may be coupled in four per liner. When the air guides 70 are coupled to each other in a plurality, the spacing is constant. It is possible to change the design so as to maximize the air suction efficiency in consideration of the rotating direction of the bucket 10 without matching the arrangement intervals of the air guides 70 if necessary.

The air guide 70 may protrude from the outer surface of the bucket 10 and may have an inlet that has a predetermined inclination and is inclined toward the direction in which the bucket 10 rotates.

Fig. 3 is a view showing a coupling relation between the bucket and the air guide, Fig. 4 is a plan view of Fig. 3, and Fig. 5 is a side view of Fig.

3 to 5, the air guide 70 is inclined at a predetermined angle so that the air outside the bucket 10 can be smoothly entered into the bucket 10 when the bucket 10 rotates . The inclination angle? Of the inlet of the air guide 70 can be made to be about 25 to 35 degrees with respect to the horizontal surface of the bucket 10. Thus, when the bucket 10 rotates, external air flows into the inlet of the air guide 70 through the inclined entrance of the air guide 70, and air introduced into the air guide 70 passes through the air guide 70 And then guided to the air hole 100 of the bucket 10. Then, the air guided to the air hole 100 flows into the bucket 10 through the air hole 100 of the bucket 10.

The air inlet opening / closing member may be further coupled to the air guide 70 according to an embodiment of the present invention.

FIG. 6 is a view showing a state in which the air inlet opening and closing member is coupled to the air guide, and FIG. 7 is a sectional view showing the coupling relationship between the bucket, the air guide, and the air inlet opening and closing member.

6 and 7, the air inlet opening and closing member includes a damper 71, a damper shaft 72, a damper weight bracket 73, a damper weight rod 74, and a damper weight 75.

The damper 71 is coupled to the inlet of the air guide 70 and functions to open and close the inlet of the air guide 70 according to the external force. The damper 71 is attached to the inlet of the air guide 70 and functions as a kind of door so that the damper 71 can be opened to the inside of the air guide 70 through the inlet of the air guide 70 according to the degree of opening and closing of the damper 71 It is possible to control the amount of the air flowing into the apparatus. The damper 71 is opened or closed according to the position of the damper weight 75.

The damper shaft 72 is coupled with the damper 71 and functions to support the damper 71. The damper shaft 72 is inserted into and engaged with the holes on both sides of the inlet of the air guide 70. Both ends of the damper shaft 72 are fitted in the holes of the air guide 70 and are rotatably supported. The damper shaft 72 is fixedly coupled to the damper 71 and rotates together. The damper weight 75 causes the damper 71 to be interlocked and closed by gravity, and to be opened by the centrifugal force. The weight of the damper weight 75 can be changed in design with respect to the self weight of the damper 71 and the opening and closing operation of the damper 71. [ The damper weight bracket 73 is a portion for assembling the damper 71 and the damper weight 75. The damper weight (75) rod (74) serves to connect the damper weight (75) and the damper weight bracket (73).

The operation of the air inlet opening / closing member will be described on the assumption that the bucket 10 is rotated with reference to FIG.

When the bucket 10 starts rotating, the damper weight 75 is moved toward the edge of the bucket 10 by the centrifugal force. The upper damper 71 is opened so that the air entering the air guide 70 enters the bucket 10 through the air hole 100.

Then, the air introduced into the bucket 10 functions to promote the combustion of unburned glow-in coke. On the other hand, when the rotation of the bucket 10 is stopped after the extrusion is completed, the damper weight 75 is moved toward the center of the bucket 10 by gravity. And the upper damper 71 is closed to prevent the flame inside the bucket 10 from being blown out of the bucket 10. [

1 is a view showing a coke bucket of a dry fire extinguishing system according to an embodiment of the present invention.

2 is a partial cross-sectional view schematically showing a state in which outside air is introduced into the bucket through an air guide.

3 is a view showing a coupling relationship between the bucket and the air guide.

Fig. 4 is a plan view of Fig. 3. Fig.

5 is a side view of Fig.

6 is a view showing a mounted state of the air inflow opening / closing member coupled to the air guide.

7 is a cross-sectional view showing a coupling relationship between the bucket, the air guide, and the air inlet opening / closing member.

Description of the Related Art

10: bucket 12: cover

70: air guide 71: damper

72: damper shaft 73: damper weight bracket

74: damper weight rod 75: damper weight

100: air hole

Claims (5)

A bucket for loading the coke in an inner space with one side opened, and At least one outer surface of the bucket having an inlet for guiding the outside air of the bucket into the bucket when the bucket rotates, / RTI > Wherein the bucket has an air hole at a portion where the air guide is engaged and the air hole is formed such that when the bucket rotates, the outside air of the bucket flows into the bucket through the inlet of the air guide and the air hole And a coke bucket of a dry fire extinguishing system which burns out the poorly heated red coke by extruding the air through the air hole into the bucket. The method according to claim 1, Wherein the air guide protrudes from an outer surface of the bucket and has an inlet formed to have a predetermined inclination and to be inclined toward a direction in which the bucket rotates. 3. The method of claim 2, Wherein the angle of inclination of the inlet of the air guide is between 25 and 35 degrees Celsius. The method according to claim 1, And an air inlet opening / closing member coupled to the air guide. 5. The method of claim 4, The air inlet opening / closing member A damper coupled to an inlet of the air guide and opening / closing an inlet of the air guide according to an external force; A damper shaft for supporting the damper; A damper weight for interlocking the damper by gravity and closing the damper, A damper weight bracket for assembling the damper and the damper weight, A damper weight rod connecting the damper weight and the damper weight bracket; A coke bucket of a dry fire extinguishing plant.

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