KR101388037B1 - Removing device of accumulated mineral - Google Patents

Abstract

The present invention relates to a removal device for accumulated mineral comprises a fixed chute part for guiding a transferring object; a variable stone part inserted into the fixed chute part to remove accumulated mineral; a driving part connected to the variable stone part to move the variable stone part; and a pressurization part mounted on a shuttle chute part for supplying a transferring object to the fixed chute part to pressurize the driving part as the shuttle chute part moves. Therefore, the removal device for accumulated mineral prevents accumulated mineral from solidifying.

Description

Accumulated Light Removal Device {REMOVING DEVICE OF ACCUMULATED MINERAL}

The present invention relates to a cumulative light removing device, and more particularly, to a cumulative light removing device for removing the accumulated light attached to the inside to facilitate the transport of minerals.

In general, fuel or raw materials used in steel mills are transported by belt conveyors and then placed in cells or bins by tripper cars.

That is, the tripper car distributes fuel or raw materials to a plurality of hoppers while traveling repeatedly a predetermined section along the rail.

In this case, since the tripper car is stopped corresponding to each hopper and supplies fuel or raw materials to each hopper, the tripper car repeatedly runs and stops along the rail.

On the other hand, the background art of the present invention is disclosed in Korean Patent Laid-Open Publication No. 2010-0076237 (published on Jul. 6, 2010, entitled TRIPER TRANSFER DEVICE).

SUMMARY OF THE INVENTION An object of the present invention is to provide a cumulative light removing device which frequently removes minerals accumulated inside the chute and prevents the chute from clogging due to the fixation of minerals.

Accumulated light removing apparatus according to the present invention comprises a fixed chute for guiding the conveyed material; A variable stone part inserted into the fixed chute part to remove accumulated minerals; A driving unit connected to the variable stone unit and moving the variable stone unit; And a pressurizing unit mounted on the shuttle chute unit for supplying a conveyed object to the fixed chute unit and pressurizing the driving unit as the shuttle chute unit is moved.

The fixed chute portion is arranged in a straight line, a plurality of fixing chute is reduced in width toward the bottom; And a plurality of stone boxes formed on the fixed chute and forming a layer to prevent wear due to falling of the conveyed object, wherein the variable stone part is inserted between the stone boxes to push accumulated minerals.

The fixing chute is mounted to the stone box, characterized in that it further comprises a support roller for supporting the variable stone.

The driving unit is a power transmission unit is pressed by the pressing unit; A direction change unit coupled to the power transmission unit and moved up and down and connected to the variable stone unit; And an elastic support for elastically supporting the redirection unit.

The power transmission unit passes through the sidewalk plate formed on the upper side of the fixed chute portion transfer roller portion disposed on the movement path of the pressing portion; And coupled to the transfer roller portion, characterized in that it comprises a transfer support portion disposed below the sidewalk plate.

The shifting unit is coupled to the transmission support portion protrudes downward, and vertical movement to move up and down in conjunction with the transmission support; And a link coupling portion having both ends of the vertical moving portion and the variable stone portion coupled to each other to move the variable stone portion.

The elastic support portion is coupled to the fixed chute portion, the elastic plate through which the vertical movement portion; And an elastic body seated on the elastic plate and elastically supporting the vertical moving part.

The cumulative light removing apparatus according to the present invention continuously removes the minerals accumulated in the stone box, thereby preventing the accumulation of accumulated light.

In the cumulative light removing device according to the present invention, since the variable stone part is moved by the pressing force of the pressurizing part, there is an effect of not requiring a separate power source for driving the variable stone part.

The cumulative light removing device according to the present invention has an effect of returning the variable stone part to its original position by the restoring force of the elastic support part when the pressing force of the pressing part is released.

1 is a view schematically illustrating a tripper device to which a cumulative light removing device according to an exemplary embodiment of the present invention is applied.
2 is a view schematically showing an accumulated light removing apparatus according to an embodiment of the present invention.
3 is a view schematically showing a state in which the pressing unit presses the driving unit before the shuttle chute unit enters the fixed chute unit in the cumulative light removing apparatus according to the exemplary embodiment of the present invention.
FIG. 4 is a view schematically showing a state in which the shuttle chute part is disposed in FIG. 3 and disposed above the fixed chute part.
FIG. 5 is a view schematically illustrating a state in which the pressing unit presses the driving unit while the shuttle chute unit is moved and passes through the fixed chute unit in FIG. 4.

Hereinafter, with reference to the accompanying drawings will be described an embodiment of the cumulative light removing apparatus according to the present invention. In this process, the thicknesses of the lines and the sizes of the components shown in the drawings may be exaggerated for clarity and convenience of explanation. In addition, the terms described below are terms defined in consideration of the functions of the present invention, which may vary depending on the intention or custom of the user, the operator. Therefore, definitions of these terms should be made based on the contents throughout this specification.

1 is a view schematically illustrating a tripper device to which a cumulative light removing device is applied according to an embodiment of the present invention, and FIG. 2 is a view schematically showing a cumulative light removing device according to an embodiment of the present invention.

3 is a view schematically showing a state in which the pressurizing unit pressurizes the driving unit before the shuttle chute unit enters the fixed chute unit in the cumulative light removing apparatus according to the exemplary embodiment of the present invention, and FIG. FIG. 5 is a view schematically showing a state in which the movable chute is disposed above the fixed chute unit, and FIG. 5 is a diagram schematically illustrating a state in which the pressurizing unit presses the driving unit while the shuttle chute unit is moved and passes through the fixed chute unit in FIG. 4.

1 and 2, the cumulative light removing device 1 according to an embodiment of the present invention includes a fixed chute 10, a variable stone 20, a driving unit 30, and a pressing unit 40. It is provided.

The fixed chute part 10 guides the conveyed object to be dropped through the shuttle chute part 50. The stationary chute 10 is arranged in a row with a plurality of spaced apart.

The variable stone portion 20 is inserted into the fixed chute portion 10. The variable stone unit 20 is moved left and right to remove the mineral accumulated in the fixed chute (10).

The driving unit 30 is connected to the variable stone unit 20 and transmits the pressing force of the pressing unit 40 to the variable stone unit 20 to move the variable stone unit 20.

The pressing unit 40 is mounted to the shuttle chute unit 50. The pressurizing part 40 pressurizes the driving part 30 while interlocking with the shuttle chute part 50.

For example, the pressing portion 40 is coupled to the shuttle chute 50, the side bar 41 protruding in the lateral direction, the vertical bar 42 protruding downward from the side bar 41, and the vertical bar 42 It is coupled to the lower end of the horizontal bar 43 is provided with a horizontal length.

The side bars 41 are respectively coupled to the outer side of the pair of sides arranged on a vertical line with respect to the movement route among the four surfaces of the shuttle chute 50.

The horizontal bar 43 includes a horizontal plate 431 disposed horizontally, and an inclined plate 432 formed at both ends of the horizontal plate 431 and having an inclination.

The pressing unit 40 may be further provided with a pressing roller 44. The pressure roller 44 is coupled to the shuttle chute 50 to move along the guide rail 45 to support the shuttle chute 50.

When the pressure roller 44 is added, the side bar 41 may be coupled to the pressure roller 44, or may be directly coupled to the shuttle chute 50.

Meanwhile, the tripper car 100 is reciprocated along the tripper rail 110. The tripper car 100 includes a tripper belt 120 for supplying a conveyed object, and a shuttle chute unit 50 for guiding the conveyed object supplied through the tripper belt 120 to the fixed chute unit 10. do.

Therefore, when the tripper 100 is paused, the shuttle chute 50 is positioned above any one of the fixed chute 10 to guide the conveyed material.

Then, when the tripper 100 is moved, the shuttle chute unit 50 is moved toward the other stationary chute 10 through one of the stationary chute (10).

1 to 5, the fixing chute 10 according to an embodiment of the present invention includes a fixing chute 11 and a stone box 12.

The plurality of stationary chutes 11 are arranged in a straight line. The fixed chute 11 has a shape in which the width thereof decreases downward.

For example, the sidewalk plate 15 is provided with a plurality of passage holes 16 which are spaced in a straight line, and the fixing chute 11 corresponding to the passage hole 16 is disposed below the sidewalk plate 15, respectively. do.

The fixed chute 11 may be spaced apart from the bottom surface of the sidewalk plate 15, or may be connected to the bottom surface of the sidewalk plate 15.

The stone box 12 is formed in the stationary chute 11, and forms a layer to prevent wear due to the falling of the conveyed material.

Therefore, when the conveyed matter accumulates in the stone box 12, the conveyed matter supplied through the shuttle chute 50 contacts the conveyed matter accumulated in the stone box 12 to prevent damage to the fixed chute 10. do.

For example, as long as the fixing chute 11 has a rectangular cross-section and the stone box 12 is arranged on the same line as the traveling direction of the shuttle chute 50, among the four surfaces of the fixing chute 11. It is formed on each side of the pair.

In addition, three stone boxes 12 are disposed on each side up and down to form a staircase-like layer, and the transfer material accumulates on the upper side of each stone box 12.

On the other hand, the variable stone portion 20 is inserted between each stone box 12, to push the accumulated mineral on the upper side of the stone box (12).

The fixing chute 10 according to the embodiment of the present invention is further provided with a support roller 13. The support roller 13 is mounted to the stone box 12 to support the variable stone portion 20 is inserted between the stone box 12.

For example, the support roller 13 includes a support 131 coupled to the stone box 12, a roller 132 coupled rotatably to the support 131, and supporting the variable stone part 20. do.

When the three stone boxes 12 are spaced up and down, and the two variable stone portions 20 are inserted therebetween, the support rollers 13 are mounted on each of the stone boxes 12 forming the middle layer and the lowest layer. The variable stone part 20 is supported.

The driving unit 30 according to an embodiment of the present invention is provided with a power transmission unit 60, a direction change unit 70, and an elastic support unit 80.

The power transmission unit 60 is disposed on the movement path of the pressing unit 40. The power transmission unit 60 is pressed by the pressing unit 40 is moved downward.

Direction switching unit 70 is coupled to the power transmission unit 60 is moved up and down. The direction change unit 70 is linked to the variable stone unit 20. As a result, the direction change unit 70 is moved up and down while pushing or pulling the variable stone unit 20.

The elastic support part 80 elastically supports the turning part 70. The elastic support 80 provides a restoring force to the turning unit 70.

Power transmission unit 60 according to an embodiment of the present invention is provided with a transmission roller portion 61 and the transmission support portion (62).

The transfer roller portion 61 penetrates the sidewalk plate 15 and is disposed on the movement path of the pressing portion 40.

For example, the transfer roller unit 61 is disposed between the coupling stage 611, a pair of roller stages 612 coupled to the coupling stage 611, and the roller stage 612, and the roller stage 612. It is provided with a transfer roller 613 is rotatably coupled to.

The transfer roller portion 61 is disposed on each movement path of the pair of pressing portions 40 and moves vertically through the sidewalk plate 15 through the sidewalk hole 17 formed in the sidewalk plate 15. do.

The delivery support part 62 is coupled to the delivery roller part 61 and disposed below the sidewalk plate 15.

For example, the transmission support part 62 is provided with a support 621 coupled to each coupling table 611 and protruding downward, and a connection table 622 connecting the pair of supports 621. The connecting table 622 is disposed perpendicular to the movement path of the shuttle chute 50.

The turning unit 70 according to an embodiment of the present invention is provided with a vertical moving unit 71 and a link coupling unit 72.

The vertical moving part 71 is coupled to the transmission support part 62 and protrudes downward. The vertical moving unit 71 is moved up and down in conjunction with the transmission support 62.

Both ends of the link coupling portion 72 are coupled to the vertical moving portion 71 and the variable stone portion 20. The link coupling portion 72 pushes or pulls the variable stone portion 20 as the vertical movement portion 71 is moved up and down.

For example, the two link coupling portions 72 are respectively coupled in the longitudinal direction of the vertical moving portion 71 so as to correspond to the two variable stone portions 20 arranged up and down. The link coupling portion 72 has an inclination to smoothly move the variable stone portion 20.

An elastic support portion 80 according to an embodiment of the present invention is provided with an elastic plate 81 and an elastic body 82.

The elastic plate 81 is coupled to the fixed chute 10 and extends to have a length parallel to the movement path of the shuttle chute 50. The vertical plate 71 penetrates the elastic plate 81. For example, the elastic plate 81 is coupled to the lowermost stone box 12.

The elastic body 82 is mounted on the elastic plate 81 to elastically support the vertical moving part 71. For example, the elastic body 82 has a coil spring shape surrounding the vertical moving part 71, and the moving protrusion 73 is caught and supported by the elastic body 82 in the vertical moving part 71.

In this case, the moving protrusions 73 may be disposed to be spaced apart from each other in the longitudinal direction of the vertical moving portion 71 to be coupled to each link coupling portion 72.

Referring to the operation and effect of the cumulative light removing device according to an embodiment of the present invention having the structure as described above are as follows.

When the pressurizing portion 40 presses the transfer roller portion 61 positioned on the left side of the fixed chute portion 10 while the shuttle chute portion 50 is moved from left to right, the transfer roller portion 61 moves downward. (See FIG. 3).

When the transfer roller portion 61 is moved downward, the transfer support portion 62 is moved downward while the elastic body 82 is contracted, the link coupling portion 72 is linked to the variable stone portion 20, the variable stone portion 20 ) To remove the minerals accumulated in the stone box (12).

In the state of FIG. 3, when the shuttle chute 50 moves in the right direction and is positioned above the fixed chute 10, the conveyed goods discharged from the shuttle chute 50 are supplied to the fixed chute 10. The transfer material accumulates in each stone box 12 to suppress the breakage of the fixed chute 10 (see FIG. 4).

At this time, since the pressure on the power transmission unit 61 positioned on the left side of the fixed chute unit 10 is released, the vertical movement unit 71 and the power transmission unit 60 connected thereto are restored by the restoring force of the elastic body 82. Returning to the original position, the link coupling portion 72 pulls the variable stone portion 20.

When the feed supply to the fixed chute 10 is completed in FIG. 4, the shuttle chute 50 is moved to the right to supply the feed to the other fixed chute 10 (see FIG. 5).

At this time, when the pressurizing portion 40 presses the transfer roller portion 61 positioned on the right side of the fixed chute portion 10, the transfer roller portion 61 is moved downward.

When the transfer roller portion 61 is moved downward, the transfer support portion 62 is moved downward while the elastic body 82 is contracted, the link coupling portion 72 is linked to the variable stone portion 20, the variable stone portion 20 ) To remove the minerals accumulated in the stone box (12).

The cumulative light removing apparatus 1 according to the exemplary embodiment of the present invention continuously removes the minerals accumulated in the stone box 12, thereby preventing the accumulation of accumulated light.

In the cumulative light removing device 1 according to the exemplary embodiment of the present invention, since the variable stone unit 20 is moved by the pressing force of the pressing unit 40, a separate power source for driving the variable stone unit 20 is required. Do not

In the cumulative light removing apparatus 1 according to the exemplary embodiment, when the pressing force of the pressing unit 40 is released, the variable stone unit 20 may be returned to its original position by the restoring force of the elastic support unit 80.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it will be understood by those of ordinary skill in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims. I will understand.

Accordingly, the true scope of protection of the present invention should be defined by the following claims.

10: fixed chute part 11: fixed chute
12: stone box 13: support roller
15: press board 16: press hall
20: variable stone part 30: driving part
40: press portion 41: side bar
42: vertical bar 43: horizontal bar
44: pressure roller 45: guide rail
50: shuttle chute unit 60: power transmission unit
61 transfer roller portion 62 transfer support portion
70: turning part 71: vertical moving part
72: link coupling portion 73: moving projection
80: elastic support 81: elastic plate
82: elastic body

Claims (7)

A fixed chute unit for guiding the conveyed material;
A variable stone part inserted into the fixed chute part to remove accumulated minerals;
A driving unit connected to the variable stone unit and moving the variable stone unit; And
It is mounted to the shuttle chute unit for supplying the transfer to the fixed chute unit, and includes a pressing unit for pressing the drive unit as the shuttle chute unit is moved,
The fixed chute part
A plurality of stationary chutes arranged in a straight line and decreasing in width downward; And
It is formed in the fixed chute, and comprises a plurality of stone box to form a layer to prevent wear due to falling of the conveyed material,
Accumulated light removing device, characterized in that the variable stone unit is inserted between the stone box to push the accumulated minerals.
delete The method of claim 1, wherein the fixing chute part
And a support roller mounted to the stone box and supporting the variable stone part.
2. The apparatus of claim 1, wherein the driving unit
A power transmission unit pressurized by the pressing unit;
A direction change unit coupled to the power transmission unit and moved up and down and connected to the variable stone unit; And
Accumulated light removing device comprising an elastic support for elastically supporting the redirection unit.
5. The power transmission apparatus according to claim 4,
A transmission roller part disposed on a moving path of the pressing part by penetrating a sidewalk plate formed on the fixing chute part; And
Cumulative light removal device, characterized in that coupled to the transfer roller portion, comprising a transfer support portion disposed below the sidewalk plate.
The method of claim 5, wherein the redirection unit
A vertical moving part coupled to the delivery support part to protrude downward and moved up and down in association with the delivery support part; And
Both ends of the vertical movement portion and the variable stone portion are coupled to the link, cumulative light removal device comprising a link coupling portion for moving the variable stone portion.
The method of claim 6, wherein the elastic support portion
An elastic plate coupled to the fixed chute part and penetrating the vertical moving part; And
And an elastic body seated on the elastic plate and elastically supporting the vertical moving part.

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