KR101322157B1 - Apparatus for opening and closing leveller's door - Google Patents

Abstract

The present invention is installed on the device frame and the rotating member rotatably connected on the device frame and the opening and closing portion connected to the rotating member to open and close the leveler door and installed on the rotating member to move the opening and closing portion between the operating position and the standby position. A leveler door opening and closing device provided with a first driving unit and a buffer unit connected to the opening and closing unit to alleviate a load received by the first driving unit due to a deviation and a deviation between a leveler door and the first driving unit forward value. According to the present invention, in addition to the effect of completely closing the leveler door, it is configured in consideration of the deviation between the leveler doors due to the displacement generated in the leveler door. By minimizing this, the life extension effect of the cylinder can be expected.

Description

Leveler door opening and closing device {Apparatus for opening and closing leveller's door}

The present invention relates to a leveler door opening and closing device, and more particularly, to a leveler door opening and closing device configured to solve a problem of opening and closing of a leveler door.

In general, as shown in FIG. 1, a coke oven 10 having a plurality of carbonization chambers 11 includes about 1240 after charging coal using a charging vehicle 12. It is a facility used to produce off-white coke from which volatiles contained in coal are removed by blocking and heating external air for about 26 hours at a temperature higher than ℃.

The above operation using the coke oven 10 is also referred to as a 'drying operation', and after the drying operation, the coke draws the main door 21 of the carbonization chamber 11 and opens it, and the ram of the extruder 13. It is discharged from the carbonization chamber by 22 and loaded into a fire truck (not shown) through the coke guide of a transfer car (not shown), and is then transferred to a fire extinguishing tower for extinguishing.

When the coke is discharged from the carbonization chamber 11 as described above, the extruder 13 and the transfer car close the carbonization chamber main door 21, and reload the coal into the carbonization chamber 11 to dry-dry the operation. Repeat this.

Meanwhile, as shown in FIG. 1, when coal is charged into the carbonization chamber 11, a leveling operation is required to uniformize the loading state of the coal. For this purpose, a leveler installed to reciprocate on the upper right side of the ram 22 of the extruder 13. The beam 23 is used.

For example, as shown in FIG. 1, when coal is charged into the carbonization chamber 11 of the coke oven 10, the leveler beam 23 of the extruder 13 is advanced to flatten the level of the charged coal. To this end, a leveler door 24 (also referred to as a 'small door') is installed above the main door 21 of the carbonization chamber 11 to open and close a passage through which the leveler beam 23 enters the carbonization chamber 11. It is.

At this time, the leveler door 24 of such a carbonization chamber is opened by the leveler door opening and closing device 14 installed in the extruder 13, as shown in Figs.

On the other hand, as shown in FIG. 1, the reason for flattening the coal charged into the carbonization chamber 11 by using the leveler beam 23 is that the coke oven gas generated when coal coal distillation is formed in the rising pipe ( It is to be discharged smoothly through 15).

However, as shown in FIG. 2, the leveler door 24 (small door) must first be opened by using the leveler door opening and closing device 14 for entering the carbonization chamber 11 of the leveler beam 23.

On the other hand, the leveler door 24 is provided to the upper side of the carbonization chamber main door 21, is installed in a hinge structure on one side of the rectangular retainer through which the leveler beam 23 passes.

Therefore, as shown in FIGS. 2 and 3, the hook portion 14a of the open arm 14b of the leveler door opener 14 is caught by the lever of the leveler door 24 while the leveler door opener 14 is closed. By operation of the leveler door 24 is raised open.

When the charging of the coal in the charging car 12 is completed, the extruder 13 closes the leveler door 24. At this time, when the leveler door 24 is closed, the roller 14d is closed by closing the leveler door lever by the opening / closing cylinder 14c, and the leveler door lever is bounced up by the elasticity of the roller 14d descending to be hooked. Peeling off occurs.

As a result, the leveler door 24 is not completely closed. Even if the leveler door 24 is closed, the leveler door 24 is opened while the lever is slightly removed from the hook after a certain time has elapsed.

When the leveler door 24 is not completely closed and opened slightly, a gap is formed between the door frame and the sealing strip, and a large amount of gas generated by coal distillation leaks between the gaps, increasing air pollution. As coal generated by coal distills leaks out and is fixed, it causes a failure of closing the leveler door 24 and causes gas leakage.

In addition, a displacement occurs in the leveler door 24 due to the high temperature generated in the carbonization process of the coke oven, and thus a deviation occurs between the leveler doors 24, thereby setting the setting value that the opening and closing cylinder 14c is completed. In order to fix the pressure of the leveler door 24, the function of the hook is not properly used due to the deviation of the opening / closing cylinder 14c, or the opening / closing cylinder 14c is subjected to a load. There is a problem of shortening the life of (14c).
The prior art relating to the opening and closing of coke oven leveler doors is publication number 10-2009-0125951.

Accordingly, there is a need in the art for a leveler door opening and closing device that can not only completely close the leveler door, but also control the deviation even if a displacement occurs in the leveler door due to the high temperature to buffer the load generated in the open / close cylinder. have.

In order to achieve the above object, an embodiment of the present invention provides a leveler door opening and closing device as follows.

Leveler door opening and closing device of the present invention is provided on the device frame and the rotating member which is rotatably connected on the device frame and the opening and closing portion for opening and closing the leveler door in conjunction with the rotating member and the device is provided to move the rotating member. It is provided on the drive unit and the rotating member and in conjunction with the opening and closing portion may be configured to include a buffer provided to buffer the load received by the drive due to the deviation of the leveler door.

Here, the drive unit may be configured to be spaced apart from the rotating shaft of the rotating member, the drive cylinder to enable the rotating member to rotate at a predetermined angle.

In addition, the opening and closing portion may be configured with a first lever which is installed to form a rotating shaft at the end of the rotating member and the opening and closing means located at one end of the side approaching the leveler door from the first lever.

Specifically, the opening and closing means may be in the form of a hook ring, forming a lower end of the hook and opening the leveler door by hanging the leveler door lever from the bottom and forming the top of the hook and a leveler door lever It can be configured with a closed ring to close the leveler door to hang from above.

The leveler door opening and closing device of the present invention may further include a second driving part connected to the shock absorbing part and transmitting an external force to the shock absorbing part.

Here, the second drive unit may be configured by a cylinder connected to the buffer unit and the second lever and driving the buffer unit.

In addition, the buffer portion may be provided with an elastic means connected to the opening and closing portion and the white paper block to provide a buffer force to the opening and closing portion.

Specifically, the elastic means and the guide beam configured to be adjustable in length

It is installed along the circumference of the guide beam may be provided with a tension spring to provide a buffer force to the guide beam and a cover surrounding the guide beam and the tension spring is installed.

One embodiment of the leveler door opening and closing device of the present invention through the above configuration, it is possible to close the leveler door completely, there is an effect that can be prevented when the leveler door lever is lifted off the ring.

Accordingly, it is possible to prevent air pollution by suppressing a large amount of gas leakage caused by coal drying, which may occur when the leveler door is not completely closed, and a leveler door closing failure due to tar generated between the leveler door gaps. There is also an effect that can be prevented.

In addition, it is designed to take into account the deviation between each leveler door due to the displacement generated in the leveler door due to the high temperature generated during the carbonization of the coke oven, thereby minimizing the load on the open / close cylinder and extending the life of the open / close cylinder. You can also expect the effect.

1 is a block diagram illustrating an extruder having a coke oven, a leveler door opener, and a leveler beam.
2 is a view showing a conventional leveler door opening and closing apparatus.
3 is a view showing a state in which a conventional leveler door opening and closing device opens the leveler door.
Figure 4 is a configuration showing an enlarged view of the leveler door opening and closing means and the shock absorber and the inventor of the present invention.
5 is a view showing a position in the OFF position of the present invention leveler door opening and closing apparatus.
Figure 6 is a view showing the position in 1-position of the leveler door opening and closing apparatus of the present invention.
Fig. 7 is a view showing the position in 2-position of the present invention leveler door opening and closing apparatus.
Fig. 8 is a view showing the position in 3-position of the present invention leveler door opening and closing apparatus.
Fig. 9 is a view showing the position in 4-position of the present invention leveler door opening and closing apparatus.
Fig. 10 is a view showing the position in 5-position of the present invention leveler door opening and closing apparatus.
Fig. 11 is a view showing the position in 6-position of the present invention leveler door opening and closing apparatus.
Fig. 12 is a view showing the position in 7-position of the present invention leveler door opening and closing apparatus.
Figure 13 is a view showing the position in the closed position of the present invention leveler door opening and closing apparatus.

Hereinafter, with reference to the accompanying drawings to describe a specific embodiment of the present invention.

4 is a block diagram showing an enlarged view of the leveler door opening and closing device 100, the opening and closing means 210 and the buffer unit 300 of the present invention.

Referring to Figure 4, the leveler door opening and closing device 100 of the present invention is connected to the device frame 110, the rotating member 120, which is rotatably connected on the device frame 110, the rotating member 120 And an opening and closing part 200 to open and close the leveler door, and a first driving part 400 and the opening and closing part 200 installed in the rotating member 120 to move the opening and closing part 200 between an operation position and a standby position. It can be seen that the configuration consists of a buffer unit 300 and a second drive unit 500 for transmitting power to the buffer unit 300 is connected to.

Specifically, the apparatus frame 100 is installed in the extruder portion of the coke oven, the apparatus frame 100 has a plate-shaped die 101 made of steel or the like and the first drive unit (101) on the plate-shaped die (101) A first support beam 102 installed perpendicular to the plate die 101 to support 400 and a second support beam 103 installed perpendicular to the plate die 101 to support the rotating member 120. ).

In this case, the second supporting beam 103 has a longitudinal length smaller than that of the first supporting beam 102, and is installed in a direction closer to the leveler door than the first supporting beam 102. This is to connect the rotary member 120 to the first drive unit 400 to allow the rotary member 120 to rotate to move in the leveler door direction.

The first and second receiving beams 102 and 103 may be firmly installed on the plate die 101 so as to support the driving of the first driving unit 400 and the rotating member 120.

Next, one side of the first receiving beam 102 is vertical, but the other side is provided with a support block 104 having a narrower shape from the bottom to the top, the vertical surface of the support block 104 The white paper member 131 that can be connected to the first drive unit 400 is mounted.

Although not shown in the drawing, the white paper member 131 has two protrusions having a circular groove in the center thereof, and a white paper block 420 on the first drive unit is inserted between the two protrusions to form a shaft. By being coupled by, the first drive unit 400 will enable a slight rotational change generated in the first drive unit 400 as the rotating member 120 rotates.

The first driving unit 400 connected to the first receiving beam 102 through the white paper block 420 supplies power to rotate the rotating member 120 between an operating position and a standby position. .

Here, the rotating member 120 is installed on the top of the second receiving beam 103, the rotating member 120 can rotate between the operating position and the standby position in accordance with the power transmission of the first driving unit 400. To be connected to the second support beam 103 by a shaft.

The first driving unit 400 is spaced apart from the rotating shaft of the rotating member 120 in the direction in which the opening / closing unit 200 is connected, and is mounted on the rotating member 120. This is because the rotation member 120 requires a certain distance from the rotation shaft 140 to generate a moment in order to transmit power to enable the rotation. However, in FIG. 4, the rotation shaft 140 is installed closer to the direction of the rotation shaft 140 than the opening / closing direction 200, but the rotation member 120 may be smoothly rotated and the first driving unit 400 may be free of pressure. In may be mounted to other positions on the rotating member 120.

The white paper member 121 having a circular groove in the center is located at the portion where the first driving unit 400 is connected on the rotating member 120, and the white paper member 121 is the first driving unit 400. The white paper block 410 is connected to the shaft and is configured to allow a slight rotation generated in the first driving unit 400 as the rotating member 120 rotates.

Next, the second driving unit 500 is mounted to the lower portion of the rotating member 120, the side closer to the rotating shaft 140 of the rotating member 120 in the second driving unit 500 is the rotating member ( The second lever (120) is fixed by the fastening member 510 and the opposite side of the fixed side of the second driving part 500 has a rotating shaft 133 formed at a central portion on the rotating member 120. 130 is connected to one end.

Here, the second lever 130 has circular grooves 131 and 132 formed at both ends thereof, and one end of the second lever 130 is connected to the white paper block 520 of the second driving unit by a shaft. The second lever 130 is configured to rotate smoothly as the second drive unit 500 moves forward and backward.

The opposite end of the second lever 130 connected to the second driving part 500 is connected to the white paper block 340 positioned on the buffer part 300, and the power of the second driving part 500 is increased. It serves to deliver to the buffer 300.

Next, the shock absorbing portion 300 may include an elastic means 370. In one embodiment of the elastic means 370, the guide is configured to be adjustable in length according to the driving of the second driving part 500. It is installed along the circumference of the beam 320 and the guide beam 320 is provided to surround the tension spring 310 and the guide beam 310 and the tension spring 320 to provide a buffer force to the guide beam 320 The cover 360 may be configured. In addition, the cover 360 may include a fixing pin 350 to fix the rotating member 120.

The fixing pin 350 serves to firmly fix the cover 360 so that the second driving unit 500 can be properly transmitted to the tension spring 310 and the guide beam 320 as the external force is provided. Done.

Next, the opening and closing part 200 is located at one end of the first lever 220 and the first lever 220 in the direction approaching the leveler door side, which is mounted at the opposite end of the rotating shaft 140 of the rotating member 120. It may be configured as an opening and closing means (210).

And one embodiment of the opening and closing means 210 may be in the form of a hook ring, an opening ring 211 to form a lower end of the hook ring to open the leveler door by hanging the leveler door lever from the bottom and It may be composed of a closed ring 212 to form an upper end of the hook-shaped ring to close the leveler door by hanging the leveler door lever from above.

A circular groove 222 is opposite to a portion of the first lever 220 to which the opening / closing means 210 is connected, and the circular groove 222 is connected to the buffer part 300 by a shaft. . Accordingly, the first lever 220 rotates based on the rotation shaft 221 formed at the end of the rotating member 120 according to the driving of the shock absorbing part 300, thereby rotating the opening and closing means 210 to the lever of the leveler door. Will play or solve the problem.

One embodiment of the leveler door opening and closing apparatus 100 of the present invention is as described above, and will be described below the leveler door opening and closing process according to the present invention.

However, prior to the description, the lengths, angles, and the like indicated in the drawings are approximate values measured by the operation result of the embodiment of the present invention, so that some errors may occur depending on the working environment and the operator, and the configuration of the present invention. It is to be understood that other examples within the range in which the identity is recognized as can be measured with different values.

The first and second driving units will be described below with reference to the first and second cylinders, which are examples of the first and second driving units.

 5 is a view showing a position in the OFF position of the leveler door opening and closing device 100 of the present invention, Figure 6 is a view showing a position in 1-position of the leveler door opening and closing device 100 of the present invention.

First, referring to FIG. 5, it can be seen that the leveler door opening and closing apparatus 100 of the present invention is located at an off position. As the first cylinder 400 retreats, the rotating member 120 is rotated about the rotating shaft 140 installed on the second supporting beam 103 to be lifted in the opposite direction of the leveler door.

Now, when the coal is charged by the charging vehicle into the Cocos oven, leveling is performed, and accordingly, the leveler beam must be introduced to open the leveler door to perform the leveling operation.

Referring to FIG. 6, it can be seen that the opening and closing part 200 is advanced to open the leveler door before the leveler beam is input. First, the first cylinder 400 is advanced, so that the rotating member 120 is rotated at a predetermined angle with respect to the rotating shaft 140 installed on the second support beam 103. The angle on the rotating member 120 and the second supporting beam 103 in the initial standby position is 173.1 ° and the rotating member 120 and the second supporting beam (according to the driving of the first cylinder 400). While the angle of 103 is reduced to 107.5 °, the rotating member 120 rotates in the direction of the leveler door. At this time, the angle formed by the opening and closing portion 200 and the rotating member 120 forms 72.5 °.

Next, Figure 7 is a view showing the position in 2-position of the leveler door opening and closing device 100 of the present invention, Figure 8 is a view showing the position in 3-position of the leveler door opening and closing device 100 of the present invention.

Referring first to Figure 7, the first cylinder 400 is driven to extend from the initial length (meaning the length in the standby position, less than 2014mm (length in close position)) to 2411mm, the rotating member ( 120 will rotate toward the leveler door.

After that, the second cylinder 500 is driven so that the length of the second cylinder 500 extends from the first 625 mm to 745 mm, and the elastic means 370 extends from the first length 1250 mm to 1300 mm. .

As the length of the elastic means 370 extends, the first lever 220 connected to the elastic means 370 rotates slightly based on the rotation shaft 221 connected to the end of the rotating member 120. . The angle extends from the first 72.5 ° to 94.9 °.

As the first lever 220 is enlarged to 94.9 °, the central portion of the pin-shaped ring of the opening and closing means 210 will contact the lever of the leveler door.

Here, the change in length of the elastic means 370 and the change in the angle of the first lever 220 are changed only to the extent that the opening and closing means 210 is in contact with the leveler door lever. do.

 When the leveler door lever is in contact with the central portion of the pin-shaped ring of the opening and closing means 210, the first cylinder 400 is driven to open the leveler door to rotate the rotating member 120.

Referring to Figure 8, it can be seen that the length of the first cylinder 400 shrinks from 2411mm to 2392mm. Accordingly, the rotating member 120 is rotated in the opposite direction to the leveler door and the angle is changed from 107.5 ° to 109 °.

At this time, the second cylinder 500 is not driven, and the leveler door lever is caught by the opening ring 211 of the opening and closing means 210.

In FIG. 8, it can be seen that the length of the elastic means 370 is slightly changed from 1300 mm to 1301 mm. This is because the displacement occurs in the leveler door due to the high temperature generated during the carbonization of the coke oven, and this causes a deviation between the leveler doors. It is an expression of easing. In fact, the displacement that occurs in the leveler door is a few millimeters.

That is, when the opening and closing means 210 to the lever of the leveler door, in the elastic means 370 of the buffer portion to mitigate the deviation generated between each leveler door and thereby the impact generated on the first cylinder 400 The length change occurs according to the deviation of the leveler door displacement value of 1 mm, and thus shows a process of mitigating the shock transmitted to the first cylinder 400.

As a result, the opening and closing means 210 is applied to the lever of the leveler door so as to open the leveler doors having different deviations through the above process.

Next, Figure 9 is a view showing the position in 4-position of the leveler door opening and closing device 100 of the present invention, Figure 10 is a view showing the position in 5-position of the leveler door opening and closing device 100 of the present invention. 11 is a view showing the position in 6-position of the leveler door opening and closing device 100 of the present invention, Figure 12 is a view showing the position in 7-position of the leveler door opening and closing device 100 of the present invention.

Referring to Figure 9, it can be seen pulling the lever of the leveler door to open the leveler door. Accordingly, the length of the first cylinder 400 is reduced from 2392 mm to 2324 mm, and the rotating member 120 rotates in the direction opposite to the leveler door.

In this case, too, the second driving unit 500 is not driven, but it can be seen that the elastic means 370 is reduced in length from 1301 mm to 1295 mm.

This is because the lever of the leveler door is called from the ring while the opening and closing means 210 is lifted from the lower side of the lever of the leveler door, and the direction of the first lever 220 of the first lever 220 is raised. The change in the length of the elastic means 370 is caused by the rotation. In this case, the elastic means 370 will serve to provide a close contact force so that the opening and closing means 210 can be caught by the lever of the leveler door.

Next, referring to Figures 10, 11 and 12, you can see the process of opening the leveler door. First, the first cylinder 400 is continuously changed from 2324 mm shown in FIG. 9 to 2014 mm to move to a position where the leveler door is finally opened.

As the first cylinder 400 is driven, the rotating member 120 continuously increases at an angle of 114.4 ° shown in FIG. 9 to 137.7 °. Accordingly, the opening and closing means 210 located at the end of the rotating member 120 is raised, so that the leveler door is also opened.

In this case, the second cylinder 500 is not driven, but the elastic means 370 is reduced in length from 1295 mm to 1272 mm, which is reduced by the length of the elastic means 370 to the first lever 220. By increasing the angle of rotation, the opening ring 211 of the opening and closing means 210 is to serve to keep in close contact with the lever of the leveler door.

In this open state, the leveler beam is now flattened to the coal in the coke oven so that it enters the coke oven. After finishing the leveling process, the leveler door must now be closed again to carbonize the coal.

Fig. 13 shows a state diagram showing the position in the closed position of the leveler door opening and closing apparatus 100 according to the present invention.

Referring to FIG. 13, the lever of the leveler door is caught by the sealing ring 212 of the opening and closing means 210, so that the leveler door can be closed. At this time, the first cylinder 400 rotates the rotating member 120 again in the direction of the leveler door from 2014mm to 2428mm, which is the length value in the initial opening state. Accordingly, the opening and closing means 210 connected to the end of the rotating member 120 is moved downwards, and the leveler door connected to the opening ring 211 positioned below the opening and closing means 210. The lever is caught by a closed ring 212 located at the top of the opening and closing means 210.

And it is pushed down by the rotation of the rotating member 120 and the lever of the leveler door is connected to the hook again, the leveler door is closed. At this time, the lever of the leveler door is firmly pushed in the process of extending the length of the elastic means 370 from 1272 mm to 1300 mm so as to be fully engaged with the ring.

Through the configuration and performance of the present invention as described above, the leveler door may be opened in consideration of the deviation occurring in the leveler door due to the high temperature of the coke oven, thereby preventing the shock that may occur in the first cylinder 400. Can be. It also allows the leveler door to be completely closed.

The foregoing merely illustrates a specific embodiment of the leveler door opening and closing apparatus 100.

Therefore, it should be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the present invention as defined by the following claims. do.

100 ... leveler door opener 110 ... device frame
120.Rotating member 130 ... 2nd lever
140.Rotating shaft of first drive section 140.Rotating shaft of support
200 ... opening and closing 210 ... opening and closing means
211 ... opening ring 212 ... closed ring
220 ... Lever 1 300 ... Shock Absorber
310 ... tension spring 320 ... guide beam
330 ... cover 370 ... elastic means
400 ... Driver (first drive, first cylinder)
500 ... 2nd drive part (2nd cylinder)

Claims (8)

Device frame 110; and
A rotating member 120 rotatably connected to the apparatus frame 110; Wow
An opening / closing part 200 connected to the rotating member 120 to open and close a leveler door; Wow
A driving unit 400 mounted to the apparatus frame 110 and provided to move the rotating member 120; And
A buffer unit 300 installed on the rotating member 120 and provided to buffer the load received by the driving unit 400 due to the deviation of the leveler door in connection with the opening / closing unit 200;
Wherein, the buffer unit 300 is connected to the opening and closing unit 200 and the white paper block 330, the elastic means 370 for providing a buffer force to the opening and closing portion 200; leveler door comprising a Switchgear
The method of claim 1,
The drive unit 400 is installed to be spaced apart from the rotating shaft of the rotating member 120, the leveler door opening and closing device, characterized in that the cylinder to enable the rotation of the rotating member 120 at a predetermined angle
The method of claim 1,
The opening and closing part 200 has a first lever 220 is formed to form a rotating shaft at the end of the rotating member 120; And
An opening / closing means (210) positioned at one end of the first lever (220) approaching the leveler door;
Leveler door opening and closing device comprising the
The method of claim 3,
The opening and closing means (210) is a fin-shaped ring, an opening ring (211) for forming a lower end of the fin-shaped and opening the leveler door by hanging the leveler door lever from below; And
An airtight ring 212 forming an upper end of the X-shape and hanging the leveler door lever from above to close the leveler door;
Leveler door opening and closing device comprising the
The method of claim 1,
Leveler door opening and closing device further comprises a second drive unit 500 is connected to the buffer unit 300 for transmitting an external force to the buffer unit 300.
The method of claim 5,
The second drive unit 500 is connected to the buffer unit 300 and the second lever 130, the leveler door opening and closing device, characterized in that the cylinder for driving the buffer unit 300
delete The method of claim 1,
The elastic means 370 is a guide beam 320 configured to be adjustable in length; and
A tension spring 310 installed along a circumference of the guide beam 320 to provide a buffer force to the guide beam 320; And
A cover 360 covering the guide beam 320 and the tension spring 310;
Leveler door opening and closing device comprising the

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