KR101277578B1 - Movable chute - Google Patents

Abstract

The present invention relates to a moving chute, wherein the distribution duct is installed to be movable, a plurality of guide ducts located below the distribution duct, and the attachment light adjacent to the guide duct and attached to the distribution duct is dropped. A falling light storage unit; And a fall light removal unit mounted to the distribution duct part and configured to move the fall light stored in the fall light storage part to the guide duct part.
The mobile chute according to the present invention can prevent the fall of a fall by storing the fall light by putting it into the guide duct when moving the distribution duct.

Description

Mobile Suit {MOVABLE CHUTE}

The present invention relates to a mobile chute, and more particularly, to a mobile chute that suppresses the loss of adhesion light in the process of selectively inducing the conveying material to a plurality of belt conveyors.

Typically, feeds such as fuel or raw materials used in steel mills are transported to a desired place by a plurality of belt conveyors.

Since the length of the belt conveyor can not be made infinite, a chute is provided between the belt conveyor and the belt conveyor.

The chute serves to connect the belt conveyor by forming a duct shape to guide the conveyed matter, which is conveyed from one of the belt conveyors, to fall onto the other one of the belt conveyors.

The technical structure described above is a background technique for assisting the understanding of the present invention, and does not mean the prior art widely known in the technical field to which the present invention belongs.

An object of the present invention is to provide a mobile suit that stores the attachment light so as not to fall, and guides the attachment light to the belt conveyor.

In order to achieve the above object, the present invention provides a distribution duct unit that is movable; A plurality of guide duct portions positioned below the distribution duct portion; A fall light storage unit adjacent to the guide duct part and in which attachment light attached to the distribution duct part is dropped and stored; And a fall light removal unit mounted to the distribution duct part and configured to move the fall light stored in the fall light storage part to the guide duct part.

The distribution duct unit has a plurality of distribution ducts connected to the upper end; And a moving body connected to the distribution duct to move the distribution duct horizontally.

An upper and lower removal unit mounted on the distribution duct and moved up and down; And a rotation removing unit mounted on the distribution duct and rotating.

The upper and lower removal parts are located on both sides of the distribution duct, respectively; An upper and lower locking plate extending from the upper and lower removal plates and bent to penetrate the distribution duct; And a vertical driving part configured to vertically move the vertical locking plate.

The upper and lower driving unit is fixed to the upper and lower parts of the distribution duct; A vertical rotation shaft coupled to the upper and lower parts to be rotatable; An elliptical upper and lower support coupled to the vertical rotation shaft and supporting the vertical locking plate; A vertical transfer member connected to the vertical rotation shaft and transmitting power in one direction; A vertical transfer rod coupled to the upper and lower carriers and protruding in a lateral direction; An upper and lower locking body penetrating the vertical rotation shaft and having an elliptic shape; It is coupled to the upper and lower catching body, the upper and lower catching bar protruding to be caught by the upper and lower transfer rods; And an upper and lower rail disposed on the moving path of the upper and lower locking bodies to press the upper and lower locking bodies.

The rotation elimination unit is a rotation elimination plate embedded in the distribution duct and positioned between the upper and lower elimination plates; A rotating main shaft coupled to the rotation removing plate and rotatably coupled to the distribution duct; And it characterized in that it comprises a rotary drive unit for rotating the rotating main shaft.

The rotation drive unit is connected to the rotation main shaft and a transmission for transmitting power in one direction; A rotation transfer rod coupled to the rotation carrier and protruding in a lateral direction; A rotating locking body penetrating through the rotating main shaft and having an elliptic shape; A rotating catching rod coupled to the rotating catching body and protruding to be caught by the rotating transfer rod; And a rotating rail disposed on the moving path of the rotating catching body to press the rotating catching body.

The mobile chute according to the present invention has an effect of preventing falling lights by storing the falling light storage unit even if the attachment light attached to the moved distribution duct falls.

The mobile chute according to the present invention has an effect of injecting the falling light stored in the falling light storage unit into the guide duct unit.

The mobile chute according to the present invention has an effect of preventing the interference with falls due to the vertical removal plate is raised when the distribution duct moves to the fall light removal unit.

The mobile chute according to the present invention has an effect of preventing the interference with the fall light by rotating the rotation removal plate when the distribution duct moves to the fall light removal unit.

1 is a view schematically showing a mobile chute according to an embodiment of the present invention.
FIG. 2 is a view schematically illustrating a state in which the distribution duct portion is moved to the fall light storage unit in FIG. 1.
3 is a view schematically illustrating a state in which the distribution duct is moved to the guide duct part in FIG.
4 is a view schematically showing a vertical removal unit in a mobile chute according to an embodiment of the present invention.
5 is a view schematically showing the operation relationship of the up and down drive unit while the distribution duct is moved to the fall light storage unit in the mobile chute according to an embodiment of the present invention.
6 is a view schematically showing the operation relationship of the up and down drive unit while the distribution duct is moved to the guide duct in the mobile chute according to an embodiment of the present invention.
7 is a view schematically showing a rotation removing unit in the mobile chute according to an embodiment of the present invention.
FIG. 8 is a view schematically showing an operation relationship of the rotation driving unit while the distribution duct is moved to the fall light storage unit in the mobile chute according to an embodiment of the present invention.
9 is a view schematically showing the operation relationship of the rotary drive unit while the distribution duct is moved to the guide duct in the mobile chute according to an embodiment of the present invention.

Hereinafter, with reference to the accompanying drawings will be described an embodiment of a mobile suit 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 the specification.

1 is a view schematically showing a mobile chute according to an embodiment of the present invention, Figure 2 is a view schematically showing a state in which the distribution duct is moved to the fall light storage unit in Figure 1, Figure 3 is a distribution duct in FIG. FIG. 4 is a view schematically showing a state in which a fall light is removed by moving to an additional guide duct part, and FIG. 4 is a view schematically showing a vertical removal part in a mobile chute according to an embodiment of the present invention, and FIG. 5 is an embodiment of the present invention. FIG. 6 is a view schematically illustrating an operation relationship of the up and down driving unit while the distribution duct is moved to the fall light storage unit in the mobile chute according to the present invention, and FIG. 7 is a view schematically illustrating an operation relationship of a driving unit, and FIG. 7 schematically illustrates a rotation removing unit in a mobile chute according to an embodiment of the present invention. 8 is a view schematically showing the operation relationship of the rotary drive unit while the distribution duct is moved to the fall storage unit in the mobile chute according to an embodiment of the present invention, Figure 9 is an embodiment of the present invention FIG. 1 is a view schematically showing an operation relationship of the rotation driving unit while the distribution duct is moved from the moving chute to the guide duct.

1 to 3, the mobile chute 1 according to an embodiment of the present invention includes a distribution duct part 10, a guide duct part 20, a fall light storage part 30, and a fall light removal part 40. Is provided.

The distribution duct part 10 is positioned below the input part 100 into which the conveying object is introduced to guide the conveying object to the guide duct part 20. The distribution duct part 10 is moved horizontally.

The guide duct portion 20 is located below the distribution duct portion 10. The plurality of guide ducts 20 are arranged side by side.

The fall light storage unit 30 is disposed adjacent to the guide duct unit 20. The fall light is stored in the fall storage unit 30.

That is, the attachment light is attached to the inner wall of the distribution duct portion 10, and the attachment light falls due to the movement or vibration of the distribution duct portion 10 and becomes a fall light.

When the distribution duct part 10 is positioned above the falling light storage part 30, the attachment light attached to the distribution duct part 10 falls and accumulates in the falling light storage part 30.

The fall light removing unit 40 is mounted to the distribution duct unit 10. The fall light removal unit 40 moves the fallen light stored in the fall storage unit 30 to the guide duct unit 20.

The distribution duct part 10 according to an embodiment of the present invention includes a plurality of distribution ducts 11 and a moving body 12 for horizontally moving the distribution ducts 10. At this time, the plurality of distribution ducts 11 are connected to each other and the upper end is integrally moved.

Therefore, when the distribution duct 11 is moved to the right side, the conveyed material fed from the input unit 100 is led to the guide duct unit 20 on the left side through the distribution duct 11 on the left side (see FIGS. 1 and 3). ).

Then, when the distribution duct 11 is moved to the left side and the distribution duct 11 on the left side is positioned above the fall light storage unit 30, the conveyed material introduced from the input unit 100 receives the distribution duct 11 on the right side. Guide duct 20 on the right side is guided through (see FIG. 2).

On the other hand, the bottom surface of the distribution duct 11 and the falling light storage unit 30 are spaced apart so as to prevent interference with the falling light storage unit 30 while the distribution duct 11 is moved.

The fall light removal unit 40 located in the space separated from the distribution duct 11 and the fall light storage unit 30 is the fall storage unit when the distribution duct 11 on the left side is moved to the guide duct unit 20 on the left side. The falling light stored in 30 is moved to the guide duct part 20 on the left side.

Falling light removal unit 40 according to an embodiment of the present invention is provided with a vertical removal unit 50 and the rotation removal unit 60. The vertical removal unit 50 is mounted on the distribution duct 11 and moved up and down, and the rotation removal unit 60 is mounted on the distribution duct 11 and rotated.

4 to 6, the upper and lower removal unit 50 according to an embodiment of the present invention is provided with a vertical removal plate 51, the vertical locking plate 52 and the vertical driving part 53.

The upper and lower removal plates 51 are located at both sides of the distribution duct 11, respectively. The upper and lower removal plates 51 are disposed close to the inner side of the distribution duct 11 and face each other.

The upper and lower locking plates 52 extend from the upper and lower removal plates 51 and protrude upwardly through the distribution holes 15 formed in the distribution ducts 11. The upper and lower locking plate 52 has a shape in which the upper end portion is bent.

The vertical drive unit 53 moves the vertical locking plate 52 up and down, and ultimately moves the vertical removal plate 51 up and down.

The upper and lower driving part 53 has an upper and lower locking plate 52 to prevent the vertical removal plate 51 from coming into contact with the falling light when the distribution duct 11 is moved from the guide duct part 20 to the falling light storage part 30. To increase.

In addition, the vertical drive unit 53 lowers the upper and lower locking plate 52 when the distribution duct 11 is moved from the fall light storage unit 30 to the guide duct unit 20. Thus, the upper and lower removal plate 51 is moved in the state close to the fall light storage unit 30 to guide the fall light to the guide duct unit 20.

In the upper and lower driving unit 53 according to an embodiment of the present invention, the upper and lower parts 531, the vertical rotation shaft 532, the upper and lower retardation 533, the upper and lower carriers 534, the upper and lower conveying rods 535, the upper and lower locking bodies ( 536), the upper and lower locking bar 357 and the upper and lower rails 358 are provided.

The upper and lower parts 531 are fixed to the distribution duct 11. The upper and lower parts 531 are located close to the distribution hole 15, and the bearing is provided so that the vertical rotation shaft 532 can be smoothly rotated.

The vertical rotation shaft 532 penetrates through the upper and lower parts 531 and is rotatably coupled to the upper and upper parts 531.

The upper and lower support 533 is coupled to one end of the vertical rotation shaft 532 to support the bottom surface of the upper and lower locking plates 52. The upper and lower limbs 533 have an elliptic shape. Therefore, the height of the upper and lower locking plate 52 is adjusted according to the rotation angle of the upper and lower support 533.

The vertical carrier 534 is connected to the other end of the vertical rotation shaft 532. The vertical transfer member 534 is coupled to the up and down rotation shaft 532 in a one-way clutch method to transfer power to the up and down rotation shaft 532 when rotated in one direction, and up and down rotation shaft (when rotated in another direction). 532) does not transmit power.

The vertical transfer rod 535 is coupled to the vertical transfer member 534 and protrudes laterally.

The vertical locking body 536 has a hole formed therethrough so that the vertical rotation shaft 532 passes therethrough. The vertical locking body 536 has an elliptic shape, and rotates about the vertical rotation shaft 532 as the rotation center when the upper and lower locking bodies 536 contact each other. At this time, the up and down catching body 536 is rotated alone without interlocking with the up and down rotation shaft 532.

The upper and lower locking bars 537 are coupled to the upper and lower locking bodies 536. The upper and lower locking bars 537 are formed to protrude from the upper and lower transmission bars 535 when the upper and lower locking bodies 536 are rotated.

The upper and lower rails 538 are disposed on the movement path of the upper and lower locking bodies 536, and the upper and lower locking bodies 536 are caught by the upper and lower rails 538 in the process of distributing the distribution duct 11.

Therefore, as the distribution duct 11 is moved, the upper and lower locking bodies 536 are pressed and rotated by the upper and lower rails 538. At this time, when the upper and lower locking rods 537 are caught by the upper and lower transfer rods 535, the rotational force of the upper and lower locking bodies 536 is transmitted to the upper and lower transfer members 534 to rotate the vertical rotation shaft 532.

7 to 9, the rotation removing unit 60 according to an embodiment of the present invention includes a rotation removing plate 61, a rotation main shaft 62, and a rotation driving unit 63.

The rotation elimination plate 61 is embedded in the distribution duct 11 and is positioned between the upper and lower elimination plates 51.

Rotating main shaft 62 is coupled to the rotation elimination plate 61, the both ends to the distribution duct 11 is rotatably coupled. The rotation main shaft 62 protrudes outward from the distribution duct 11 so that one end thereof is interlocked with the rotation driving part 63.

The rotation driving unit 63 rotates the rotation main shaft 62, and the rotation removing plate 61 connected to the rotation main shaft 62 rotates in association with the rotation main shaft 62.

The rotation driving unit 63 rotates so that the lower end of the rotation removing plate 61 rises in order to prevent contact with falling lights when the distribution duct 11 is moved from the guide duct part 20 to the falling light storage part 30. The removal plate 61 is rotated.

In addition, the rotation driving unit 63 rotates the rotation elimination plate 61 so that the lower end of the rotation elimination plate 61 descends when the distribution duct 11 is moved from the fall light storage unit 30 to the guide duct unit 20. Let's do it.

Thus, the rotation removing plate 61 is moved in the state close to the fall light storage unit 30 to guide the fall light to the guide duct unit 20.

The rotary drive unit 63 according to an embodiment of the present invention is provided with a rotary carrier 631, a rotary transfer rod 632, a rotary locking body 633, a rotary locking rod 634, and a rotary rail 635.

The rotary carrier 631 is connected to one end of the rotary main shaft 62. The rotation carrier 631 is coupled to the rotation main shaft 62 in a one-way clutch manner to transmit power to the rotation main shaft 62 when rotated in one direction, and rotate when rotated in another direction. No power is transmitted to the main shaft 62.

The rotary transfer rod 632 is coupled to the rotary transfer member 631 and protrudes laterally.

The rotating locking body 633 is formed with a hole through which the rotation main shaft 62 passes. The rotation catching body 633 has an elliptic shape, and rotates with the rotation main shaft 62 as the center of rotation upon contact with the rotation rail 635. At this time, the rotation catching body 633 is rotated alone without interlocking with the rotation main shaft 62.

The rotating catching bar 634 is coupled to the rotating catching body 633. The rotation catching rod 634 is formed to protrude so as to be caught by the rotation transfer rod 632 when the rotation catching body 633 rotates.

The rotary rail 635 is disposed on the movement path of the rotary locking body 633, and the rotary locking body 633 is caught by the rotary rail 635 and rotated while the distribution duct 11 is moved.

Therefore, as the distribution duct 11 is moved, the rotation catching body 633 is pressed by the rotary rail 635 to rotate. At this time, when the rotation catching rod 634 is caught by the rotation transfer rod 632, the rotational force of the rotation catching body 633 is transmitted to the rotation transfer body 631 to rotate the rotation main shaft 62.

Referring to the operation of the mobile chute according to an embodiment of the present invention having the above structure as follows.

When the distribution duct 11 positioned on the left side is positioned below the input unit 100, the guide duct unit 20 on the left side is disposed by the distribution duct 11 positioned on the left side of the conveyed material introduced through the input unit 100. ) (See FIG. 1).

In addition, when the distribution duct 11 located on the left side is moved to the left side due to the change in the length of the moving body 12 and positioned above the falling light storage unit 30, the conveyed material introduced from the input unit 100 is located on the right side. It falls to the guide duct part 20 of the right side through the distribution duct 11 (refer FIG. 2).

In the above state, when the distribution duct 11 located on the left side is moved to the right side due to the change in the length of the moving body 12 and positioned above the guide duct unit 20 on the left side, the conveyed material fed from the feeding unit 100. It falls to the guide duct part 20 of the left side through the distribution duct 11 located in the left side (refer FIG. 3).

On the other hand, when the distribution duct 11 is positioned above the falling light storage unit 30, the attachment light attached to the distribution duct 11 falls, and the falling light is stored in the falling light storage unit 30.

At this time, the falling light removal unit 40 mounted on the distribution duct 11 is moved downward so as to be in close contact with the falling light storage unit 30 so that the falling light is moved to the guide duct unit 20 when the distribution duct 11 is moved to the right. Let's do it.

Hereinafter, the operation relationship of the top and bottom removal unit 50 among the falling light removal unit 40 is as follows.

Before the distribution duct 11 is moved to the fall light storage unit 30, the long axis of the upper and lower latches 536 is vertically disposed, and the long axis of the upper and lower retainers 533 is disposed to have an inclination, and the upper and lower locking plates 52 are disposed. (Figure 5a).

When the distribution duct 11 is moved to the fall light storage unit 30 in the above state, the lower end of the upper and lower locking bodies 536 is rotated clockwise by the upper and lower rails 538, and the upper and lower locking bars 537 are also clocked. Direction is rotated (FIG. 5B).

At this time, the upper and lower locking rods 537 is caught by the upper and lower transfer rods 535 to rotate the upper and lower transfer rods 535. As the vertical transfer rod 535 is rotated, the vertical transfer member 534 rotates clockwise to rotate the vertical rotation shaft 532.

When the vertical axis of rotation 532 is rotated, the upper and lower support 533 is rotated so that the long axis is vertically disposed. Therefore, the vertical catching plate 52 is raised, and the vertical removal plate 51 connected thereto is raised to prevent interference with falling lights.

When the distribution duct 11 is positioned above the falling light storage unit 30, the upper and lower locking bodies 536 are released from the upper and lower rails 538 (FIG. 5C).

At this time, the upper and lower latching body 536 is vertically arranged in the long axis by the load, the upper and lower support member 533 is rotated so that the long axis is inclined by the weight of the upper and lower locking plate 52, the upper and lower locking plate 52 is Descends.

Accordingly, the vertical removal plate 51 is raised while the distribution duct 11 is moved to the falling light storage unit 30, thereby preventing interference between the falling light stored in the falling light storage unit 30 and the vertical removal plate 51. .

On the other hand, before the distribution duct 11 is moved to the guide duct portion 20, the long axis of the upper and lower latches 536 is arranged vertically, the long axis of the upper and lower support 533 is disposed to have an inclination and the upper and lower locking plate ( 52) (FIG. 6A).

When the distribution duct 11 is moved to the guide duct unit 20 in the above state, the lower end of the upper and lower locking bodies 536 is caught by the upper and lower rails 538 and rotated counterclockwise, and the upper and lower locking bars 537 are also Rotate counterclockwise (FIG. 6B).

At this time, the up and down catch rod 537 is not caught by the up and down transfer rod 535, the up and down transfer rod 535 is not rotated. As the upper and lower transfer rods 535 are not rotated, the upper and lower transfer members 534 are not rotated so that the upper and lower support members 533 are disposed to have an inclination.

When the distribution duct 11 is located above the guide duct portion 20, the upper and lower locking bodies 536 are released from the interference with the upper and lower rails 538 (FIG. 6C). At this time, the vertical fastening body 536 has a long axis vertically arranged by the load.

Therefore, while the distribution duct 11 is moved to the guide duct 20, the vertical removal plate 51 maintains the lowered state to approach the falling light storage unit 30, thereby falling down stored in the falling light storage unit 30. Prevents the escape of light.

Hereinafter, the operation relationship of the rotation removing unit 60 among the falling light removal unit 40 is as follows.

Before the distribution duct 11 is moved to the fall light storage unit 30, the long axis of the rotation catching body 633 is vertically arranged (FIG. 8A).

When the distribution duct 11 is moved to the fall light storage unit 30 in the above state, the lower end of the rotary locking body 633 is rotated clockwise by the rotary rail 635 and the rotary locking rod 634 is also clocked. Direction is rotated (Fig. 8B).

At this time, the rotation catching rod 634 is caught in the rotary transfer rod 632 to rotate the rotary transfer rod 632. As the rotary transfer rod 632 is rotated, the rotary transfer member 631 rotates clockwise to rotate the rotary main shaft 62.

When the rotation main shaft 62 is rotated, the rotation elimination plate 61 connected thereto is rotated to raise the lower end of the rotation elimination plate 61. This prevents the interference between the rotation removing plate 61 and the falling light.

When the distribution duct 11 is positioned above the fall light storage unit 30, the rotation catching body 633 is released from the interference with the rotation rail 635 (FIG. 8C).

At this time, the rotation catching body 633 is rotated such that the long axis is vertically disposed by the load, and the rotation main shaft 62 is rotated so that the rotation removal plate 61 is vertically disposed by the load of the rotation removing plate 61. do.

Therefore, the lower end of the rotation removing plate 61 is raised while the distribution duct 11 is moved to the falling light storage unit 30, whereby interference between the falling light and the rotation removing plate 61 stored in the falling light storage unit 30 is reduced. Is prevented.

On the other hand, before the distribution duct 11 is moved to the guide duct portion 20, the long axis of the rotary locking body 633 is disposed vertically, the rotation removing plate 61 is vertically arranged to It is in close contact with the inner wall (Fig. 9A).

When the distribution duct 11 is moved to the guide duct unit 20 in the above state, the lower end of the rotary locking body 633 is caught by the rotary rail 635 and rotated counterclockwise, and the rotary locking rod 634 is also present. Rotate counterclockwise (FIG. 9B).

At this time, the rotation catching rod 634 is not caught by the rotation transfer rod 632, the rotation transfer rod 632 is not rotated. As the rotary transfer rod 632 is not rotated, the rotary transfer member 631 is not rotated so that the rotation removing plate 61 is vertically disposed.

When the distribution duct 11 is positioned above the guide duct portion 20, the rotation catching body 633 is released from the interference with the rotation rail 635 (FIG. 9C). At this time, the long axis is vertically arranged by the load engaging body 633.

Therefore, since the rotation elimination plate 61 is not rotated and is vertically disposed while the distribution duct 11 is moved to the guide duct portion 20, the lower end portion of the rotation elimination plate 61 is stored in the fall light storage unit ( Positioned close to the upper side of 30) to move the falling light stored in the falling light storage unit 30 to the guide duct unit (20).

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: distribution duct portion 20: guide duct portion
30: falling light storage unit 40: falling light removal unit
50: upper and lower removal unit 51: upper and lower removal plate
52: up and down latching plate 53: up and down driving unit
60: rotation removal unit 61: rotation removal plate
62: rotation main shaft 63: rotation drive unit
531: upper and lower government 532: vertical axis of rotation
533: upper and lower limb 534: upper and lower delivery
535: Up and down delivery rod 536: Up and down latching body
537: up and down jam bar 538: up and down rail
631: rotating carrier 632: rotating transfer rod
633: rotating locking body 634: rotating locking rod
635: rotating rail

Claims (7)

Distribution duct unit is installed to be movable;
A plurality of guide duct portions positioned below the distribution duct portion;
A fall light storage unit adjacent to the guide duct part and in which attachment light attached to the distribution duct part is dropped and stored; And
It is mounted to the distribution duct unit, and includes a fall light removal unit for moving the falling light stored in the fall storage unit to the guide duct unit;
The fall light removing unit
A vertical removal part mounted on the distribution duct part and vertically moved; And
Moving chute, characterized in that it comprises a rotation removal unit mounted on the distribution duct. The method of claim 1, wherein the distribution duct unit
A plurality of distribution ducts having upper ends connected thereto; And
And a moving body connected to the distribution duct to move the distribution duct horizontally. delete The method of claim 1, wherein the upper and lower removal portion
Vertical removal plates positioned at both sides of the distribution duct portion;
An upper and lower locking plate extending from the upper and lower removal plates and bent to penetrate the distribution duct portion; And
Moving suit, characterized in that it comprises a vertical drive for moving the vertical locking plate up and down. The method of claim 4, wherein the vertical drive unit
Upper and lower parts fixed to the distribution duct;
A vertical rotation shaft coupled to the upper and lower parts to be rotatable;
An elliptical upper and lower support coupled to the vertical rotation shaft and supporting the vertical locking plate;
A vertical transfer member connected to the vertical rotation shaft and transmitting power in one direction;
A vertical transfer rod coupled to the upper and lower carriers and protruding in a lateral direction;
An upper and lower locking body penetrating the vertical rotation shaft and having an elliptic shape;
It is coupled to the upper and lower catching body, the upper and lower catching bar protruding to be caught by the upper and lower transfer rods; And
And a vertical rail disposed on the moving path of the upper and lower latching bodies to press the upper and lower locking bodies. The method of claim 4, wherein the rotation removing unit
A rotation elimination plate embedded in the distribution duct and positioned between the upper and lower elimination plates;
A rotating main shaft coupled to the rotation removing plate and rotatably coupled to the distribution duct unit; And
Moving suit, characterized in that it comprises a rotary drive for rotating the main shaft. According to claim 6, The rotary drive unit
A rotation carrier connected to the rotation main shaft and transmitting power in one direction;
A rotation transfer rod coupled to the rotation carrier and protruding in a lateral direction;
A rotating locking body penetrating through the rotating main shaft and having an elliptic shape;
A rotating catching rod coupled to the rotating catching body and protruding to be caught by the rotating transfer rod; And
And a rotating rail disposed on the moving path of the rotating catching body to press the rotating catching body.

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