KR20130059890A - Transfer apparatus for rotary feeder of continuous ship unloader - Google Patents

Abstract

PURPOSE: A transfer apparatus for a rotary feeder of a continuous unloader is provided to improve the transfer efficiency of objects to be transferred because a moving panel rotating along a prop part transfers the objects to be transferred of the prop part to a belt conveyor. CONSTITUTION: A transfer apparatus(1) for a rotary feeder of a continuous unloader comprises a prop part(90), a moving panel(100), and a connection member(104). The prop part is installed under a rotary feeder(20) along the circumference of the rotary feeder and loads objects to be transferred(26) dropped from the rotary feeder. The moving panel moves along the prop part to transfer the objects to be transferred in one direction. The connection member connects the moving panel and a rotary plate(24) of the rotary feeder.

Description

TRANSFER APPARATUS FOR ROTARY FEEDER OF CONTINUOUS SHIP UNLOADER}

The present invention relates to a continuous unloader, and more particularly, for a rotary feeder of a continuous unloader, which collects the conveyed drops from the rotary feeder of the continuous unloader and transfers them to a post process, thereby improving the conveying efficiency of the conveyed material. It relates to a conveying device.

Generally, iron ore and coal used as raw fuel in steel mills during blast furnace operation are transported by ship, unloaded at the pier, and transported to the yard of the factory through conveying equipment such as belt conveyor.

The conveyed material such as coal or iron ore loaded on the ship is transferred to the outside of the ship by using a bucket continuously attached to the elevator post of the continuous unloader.

Continuous unloading machine, the boom (Boom) is installed on the upper side of the body portion moving along the pier, a plurality of buckets move in a track form along the elevator post connected to one side of the boom.

The bucket located at the lower excavation part enters the storage of the ship, excavates the iron ore or coal and transports it to the outside, and the transported goods are hopper above the body along the belt conveyor provided in the boom. It is fed into the yard through several belt conveyors.

Background art of the present invention is disclosed in Korean Unexamined Patent Publication No. 2000-0020731 (published on April 15, 2000, titled invention: Bucket elevator type continuous unloading machine).

The present invention is to provide a feeder for a rotary feeder of a continuous unloader that can improve the transfer efficiency of the conveyed material, because the conveyed object dropped from the rotary feeder of the continuous unloader to be transported to the post-process. .

The feeder for the rotary feeder of the continuous unloading machine according to the present invention is installed on the lower side along the circumference of the rotary feeder, the support portion is loaded with the transport material falling from the rotary feeder, and moved along the support portion to move the transport material in one direction And a connecting member for connecting the moving panel for transferring and the rotating plate of the rotary panel and the moving panel.

In addition, the support portion includes a support body installed in the lower side of the rotary feeder in a ring shape with an open upper side and a discharge passage that extends from the lower side of the support body toward the belt conveyor and serves as a discharge passage of the conveyed material moved along the support body. It is desirable to.

In addition, the support portion preferably includes a fixing member extending from the guide member of the rotary feeder to support the support body.

In addition, the movable panel is formed in the same shape as the cross-sectional shape of the supporting portion, it is preferable that a plurality of moving panels are provided along the circumference of the rotating plate.

In addition, the present invention, it is preferable to further include a shock absorbing member of the elastic material is installed around the moving panel in contact with the support portion to reduce the impact.

In the feeder for the rotary feeder of the continuous unloading machine according to the present invention, the conveying material dropped from the rotary feeder of the continuous unloading machine is loaded on the support portion, the moving panel rotating along the support portion conveys the transport of the support portion to the belt conveyor Therefore, the conveyance efficiency of the conveyed material can be improved.

1 is a perspective view schematically showing a feeder for a rotary feeder of the continuous unloader according to an embodiment of the present invention.
Figure 2 is a perspective view schematically showing a state in which the moving member of the rotary feeder feeder of the continuous unloader according to an embodiment of the present invention is in contact with the rotary feeder.
3 is a perspective view schematically illustrating a state in which a moving member and a crushing unit rotate together with an elevator post according to an embodiment of the present invention.
4 is a plan view schematically illustrating a state in which a movable panel is installed in a support part according to an exemplary embodiment of the present invention.
5 is a cross-sectional view schematically showing the installation state of the support and the moving panel according to an embodiment of the present invention.
6 is a perspective view schematically showing a crushing unit according to an embodiment of the present invention.
7 is a block diagram of a feeder for a rotary feeder of the continuous unloader according to an embodiment of the present invention.

Hereinafter, with reference to the accompanying drawings will be described an embodiment of a feeder for a rotary feeder of the continuous unloader according to the present invention. For convenience of description, the feeder for a rotary feeder of a continuous unloader installed in an ironworks will be described as an example. 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, terms to be described below are terms defined in consideration of functions in the present invention, which may vary according to the intention or convention of a user or an operator. Therefore, definitions of these terms should be made based on the contents throughout the specification.

1 is a perspective view schematically showing a feeder for a rotary feeder of the continuous unloader according to an embodiment of the present invention, Figure 2 is a movement of the feeder for a rotary feeder of the continuous unloader according to an embodiment of the present invention 3 is a perspective view schematically illustrating a state in which a member is in contact with a rotary feeder, and FIG. 3 is a perspective view schematically illustrating a state in which a moving member and a crushing unit are rotated together with an elevator post according to an embodiment of the present invention. 5 is a plan view schematically illustrating a state in which a movable panel is installed in a support unit according to an embodiment of the present invention, and FIG. 5 is a cross-sectional view schematically illustrating an installation state of the support unit and a mobile panel according to an embodiment of the present invention. 6 is a perspective view schematically illustrating a crushing unit according to an embodiment of the present invention, and FIG. 7 is a rotary blood of a continuous unloading machine according to an embodiment of the present invention. A block diagram of a transfer device for.

1, 4 and 5, the feeder 1 for the rotary feeder of the continuous unloader according to an embodiment of the present invention, is installed on the lower side along the circumference of the rotary feeder 20 and rotary The moving part 100 and the moving panel which move the support part 90 in which the conveyance object 26 falling from the feeder 20 is loaded, and the support part 90, and conveys the conveyance object 26 in one direction. It includes a connecting member 104 for connecting the rotary plate 24 of the rotary feeder (100) and (100).

When the vessel loaded with the conveyed material 26, such as coal or iron ore, docks at the pier, the conveyed material 26 loaded on the ship is unloaded using a continuous unloader.

An excavator (not shown) is provided below the elevator post 10 provided in the longitudinal direction, and the excavator also rotates by the rotation of the elevator post 10.

The rotary feeder 20 is installed on the upper side of the elevator post 10, and the conveyed material 26 contained in the bucket transferred upward along the elevator post 10 is the belt conveyor 30 through the rotary feeder 20. Is transferred to).

The rotary feeder 20 has a cylindrical guide member which surrounds the rotating plate 24 installed in the horizontal direction along the circumference of the elevator post 10 and the conveying material 26 loaded on the upper side of the rotating plate 24 ( 22).

Since the rotating plate 24 rotates along the circumference of the elevator post 10, the conveyed object 26 supplied to the rotary feeder 20 rotates like the rotating plate 24.

A space in which the upper side is opened by the elevator post 10 and the rotary feeder 20 is formed, and the conveyed object 26 is supplied to the upper side of the rotating plate 24.

The guide member 22 is installed to be spaced apart from the elevator post 10 and fixed, and the rotating plate 24 forming the bottom surface between the guide member 22 and the elevator post 10 is an elevator post 10. Various driving members may be used within the spirit of conveying the conveying material 26 while rotating along the outside of the.

One side of the guide member 22 is opened to form a connection port and a connection chute 38 for connecting the guide member 22 and the belt conveyor 30 is provided at the connection port.

One side of the connection chute 38 extends to the inside of the guide member 22 to form a blocking member 39, and the conveyance 26 moving along the rotating plate 24 of the rotary feeder 20 is a blocking member ( Along 39) to the connection chute 38;

The belt conveyor 30, which is connected to the connection chute 38 and transfers the conveyed material 26, includes a feed belt 32 which is an endless track for conveying the conveyed material 26 such as fuel and raw materials used in steel mills, and conveyed material. It is provided on both sides of the belt 32 includes a main roller 34 for rotating the conveying belt (32).

The conveying belt 32 moving from the main roller 34 on one side to the main roller 34 on the other side is supported by the auxiliary roller 36 to prevent sagging.

The shifting member 50 and the crushing unit 60 are installed in a waiting state on the upper side of the rotary feeder 20 during normal operation of the rotary feeder 20. [

This moving member 50, when the situation in which the conveying material 26 supplied to the rotary feeder 20 is frozen, or the overloader that is not moved because the conveying material 26 is blocked occurs, the rotary feeder 20 It can be formed in various shapes within the technical concept of being lowered to the lower side in contact with the rotating plate 24 and rotates like the elevator post (10).

The linear driver 40 according to the exemplary embodiment includes a rod 44 mounted to the elevator post 10 and linearly moved.

The linear driving part 40 includes a driving body 42 which is operated by hydraulic pressure or pneumatic and moves a cylinder, and the driving body 42 is mounted on the mounting bracket 46 and fixed to the elevator post 10. .

The rod 44 protruding from the driving body 42 is provided with a plate-shaped moving member 50, and the moving member 50 is inserted into a space formed between the elevator post 10 and the guide member 22. It stops in contact with the rotating plate 24.

The moving member 50 is rotated together with the elevator post 10 in a state in which the moving member 50 is in contact with the rotary feeder 20 installed along the circumference of the elevator post 10 to connect the conveyed material 26 with the chute 38. Move to.

The side of the elevator post 10 is provided with a rail member 52 for guiding the movement of the moving member 50. Rail member 52 may be applied to a variety of shapes, including grooves in the technical spirit for guiding the longitudinal movement of the moving member (50).

As shown in FIG. 1 and FIG. 5, the shredding part 60 installed on the side surface of the moving member 50 is moved with the moving member 50 to be loaded on the rotary feeder 20. Various kinds of shredding devices can be used in the technical concept of shredding.

The crushing unit 60 according to an embodiment includes a bracket member 62 connected to the moving member 50, a rotation driving unit 64 mounted on the bracket member 62 and supplying rotational power, and a rotation driving unit ( The rotary shaft member 66 rotates by receiving the power of the 64 and the cutter member 76 protrudes out of the rotary shaft member 66 to crush the conveyed material 26.

The bracket member 62 installed in the lateral direction of the movable member 50 may be formed in various shapes within the technical concept in which the rotary driving unit 64 and the rotary shaft member 66 are installed.

The crushing unit 60 is connected to the first shaft sprocket 68 and the rotating shaft member 66 connected to the connecting shaft member 74 and the connecting shaft member 74 which are axially connected to the rotary driving unit 64. It includes a power transmission chain 70 is rotated by hanging two sprockets (72).

The rotary drive unit 64 using the electric motor is fixed to the bracket member 62 and the rotary shaft member 66 connected to the rotary drive unit 64 is rotatably mounted on the bracket member 62. [

The first sprocket 68 is installed on one side of the rotary shaft member 66, and the connecting shaft member 74 is installed to be spaced apart from the rotary shaft member 66.

The connecting shaft member 74 is also rotatably installed on the bracket member 62, and the second sprocket 72 is also installed on one side of the connecting shaft member 74.

Since the power transmission chain 70 is installed in engagement with the first sprocket 68 and the second sprocket 72, the rotational force transmitted to the first sprocket 68 is transmitted through the power transmission chain 70 to the second sprocket 72. Is passed to.

A plurality of cutter members 76 protrude to the outside of the connecting shaft member 74, the cutter member 76 is solidified in a lump shape inside the rotary feeder 20 while being rotated together with the connecting shaft member 74 Crush the feed 26.

1, 4 and 6, the rotary feeder 20 and the elevator post 10, the sensor unit 80 for detecting the position of the moving member 50 is installed.

The sensor unit 80 includes a transmitter 82 that emits light rays and a receiver 84 that receives light rays from the transmitter 82.

The transmitting unit 82 is installed on the guide member 22 and the receiving unit 84 is installed on the elevator post 10 at a predetermined interval.

The light rays emitted from the transmitter 82 are irradiated in the direction toward the elevator post 10 and received by the receiver 84, and then the rays are reflected back to the transmitter 82.

Since the receiver 84 has different positional information along the circumference of the elevator post 10, when the beam is irradiated to the receiver 84 and then reflected back to the transmitter 82, the transmitter 82 transmits the beam. Again to measure the degree of rotation of the elevator post (10).

The measurement value of the sensor unit 80 is transmitted to the control unit 86, the control unit 86 receives the measurement value of the sensor unit 80 to control the linear drive unit 40 and the crushing unit 60.

On the other hand, the rotary plate 24 of the rotary feeder 20 according to an embodiment of the present invention is rotatably installed on the upper side of the base plate 28.

The rotating plate 24 is rotated separately from the rotation of the elevator post 10 to transfer the feed 26 supplied to the rotary feeder 20 to the connection chute 38.

A separation space is formed between the rotating plate 24 and the guide member 22, and the conveyance 26 inside the rotary feeder 20 falls out of the rotary feeder 20 through the separation space.

The conveyed object 26 dropped to the outside of the rotary feeder 20 is loaded on the support part 90 provided below the rotary feeder 20.

Support portion 90 according to an embodiment, the upper side is formed in a ring shape with an open side extending from the lower side of the support body 92 and the support body 92 is installed on the lower side of the rotary feeder 20 belt conveyor ( And a discharge pipe path 96 installed toward 30.

The upper side of the support body 92 is formed in an open shape, the discharge hole 94 is formed at the bottom of one side of the support body 92, the discharge pipe passage 96 in communication with the discharge hole 94 is a belt It is installed in the direction toward the conveyance belt 32 of the conveyor (30).

The discharge passage 96 may be formed in various shapes within the technical concept of forming a discharge passage of the conveying material 26 moving along the support body 92.

The support body 92 supports the support body 92 by a plurality of fixing members 98 extending from the guide member 22 of the rotary feeder 20, and thus is fixed to the lower side of the rotary feeder 20. Is installed.

That is, the guide member 22 of the rotary feeder 20 is fixed to the body of the continuous unloader, and since the support unit 90 is fixed to the lower side of the guide member 22, the support unit 90 is a rotary feeder ( 20) is fixed to the lower side.

The moving panel 100 which moves inside the support body 92 and pushes the conveyance 26 loaded in the support body 92 in the direction toward the discharge hole 94 has a cross section of the support unit 90. It is formed in the same shape as the shape.

The moving panel 100 is connected to the rotary plate 24 of the rotary feeder 20 and rotated together with the rotary plate 24.

That is, since the plurality of connection members 104 extends outwards along the circumference of the rotating plate 24 and is connected to the moving panel 100, the moving panels 100 installed in plural along the circumference of the rotating plate 24 are provided. In conjunction with the rotation of the rotary plate 24 rotates along the inner side of the support body 92.

The cushioning member 102 provided around the movable panel 100 in contact with the supporting portion 90 is provided to reduce the impact generated when the movable panel 100 directly contacts the inner side of the supporting body 92.

The shock absorbing member 102 is formed of an elastic material, and the shock absorbing member 102 according to an embodiment forms a rubber as a main material in consideration of economical efficiency.

Hereinafter, with reference to the accompanying drawings will be described in detail the operating state of the feeder 1 for a rotary feeder of the continuous unloader according to an embodiment of the present invention.

When the conveyance 26 is overloaded or frozen light is generated in the rotary feeder 20, the elevator post 10 is rotated to a position where the rotation of the moving member 50 starts.

When the state where the elevator post 10 is moved to the set position is confirmed by the operation of the transmitter 82 and the receiver 84 constituting the sensor unit 80, the linear drive unit 40 is operated.

When the driving body 42 is operated and the rod 44 is lowered, the movable member 50 fixed to the rod 44 is also lowered along the rail member 52 to contact the rotating plate 24 of the rotary feeder 20. It stops in the state.

When the rotary drive unit 64 is operated to rotate the rotary shaft member 66, the first sprocket 68 connected to the rotary shaft member 66 is rotated.

When the first sprocket 68 is rotated, the power transmission chain 70 engaged with the first sprocket 68 and the second sprocket 72 is rotated, so that the connecting shaft member 74 together with the second sprocket 72 is rotated. Is rotated.

When the cutter member 76 is rotated together with the connecting shaft member 74, the mass 26 formed by solidifying the conveyed material 26 and the mass formed by freezing the conveyed material 26 containing water are crushed.

When the elevator post 10 rotates, the moving member 50 and the shredding part 60 rotate like the elevator post 10, and conveys the conveyed object 26 to the connection chute 38 direction.

In a state in which the conveyance 26 loaded on the rotating plate 24 is transferred to the belt conveyor 30 through the connection chute 38, the driving body 42 is operated to move the rod 44 upward.

Since the moving member 50 and the crushing unit 60 connected to the rod 44 are also moved upwards, the rotary feeder 20 in which the frozen light and the overloader are solved is normally operated.

On the other hand, the feed 26 is dropped to the outside of the rotary feeder 20 through the spaced space formed between the guide member of the rotary feeder 20 and the rotary plate 24.

This conveyance 26 is mounted inside the support body 92 provided below the rotary feeder 20.

The moving panel 100, which is rotated together with the rotary plate 24 of the rotary feeder 20, moves along the support body 92 and slides the conveyance 26 loaded in the inside of the support body 92 in one direction. Let's do it.

For example, when the rotating plate 24 is rotated in the clockwise direction, the moving panel 100 rotated like the rotating plate 24 rotates the conveyance 26 loaded inside the support body 92 in the clockwise direction. Push to transfer

The conveyed material 26 pushed by the moving panel 100 is transferred to the discharge pipe line 96 through the discharge hole 94 of the support part 90, and then a belt conveyor provided below the discharge pipe line 96. It falls to the conveyance belt 32 of (30).

According to the configuration as described above, the feeder for rotary feeder 1 of the continuous unloading machine according to one embodiment, the support unit 90 is dropped from the rotary feeder 20 of the continuous unloader 20 It is loaded on, and the moving panel 100 rotates along the support portion 90 transfers the conveying material 26 of the supporting portion 90 to the belt conveyor, it is possible to improve the transport efficiency of the conveying material 26. .

In addition, according to the present invention, while the moving member 50 and the shredding unit 60 rotates together with the elevator post 10, the conveying material 26 frozen in the rotary feeder 20 is shredded and transported to a post process, thereby transferring The transfer efficiency of the water 26 can be improved.

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.

In addition, the rotary feeder of the continuous feeder installed in the steel mill was described as an example, but this is merely exemplary, the rotary unloader of the continuous unloader according to the present invention also in the continuous unloader used for transporting other kinds of transport. Feeders for feeders can be used.

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

1: Feeder for rotary feeder of continuous unloading machine
10: elevator post
20: rotary feeder 22: guide member 24: rotating plate 26: conveyed material
30: belt conveyor 32: transfer belt 34: main roller 36: auxiliary roller 38: connection chute 39: blocking member
40: linear drive part 42: drive body 44: rod 46: mounting bracket
50: moving member 52: rail member
60: crushing portion 62: bracket member 64: rotary drive portion 66: rotary shaft member 68: first sprocket 70: power transmission chain 72: second sprocket 74: connecting shaft member 76: cutter member
80: sensor 82: transmitter 84: receiver 86: controller
90: support portion 92: support body 94: discharge hole 96: discharge pipe 98: fixing member
100: movable panel 102: buffer member 104: connecting member

Claims (5)

A support portion installed at a lower side of the rotary feeder and loaded with a drop falling from the rotary feeder;
A moving panel moved along the support to transfer the conveyed material in one direction; And
And a connection member for connecting the movable panel and the rotary plate of the rotary feeder.
The method of claim 1,
The support portion, the support body is installed on the lower side of the rotary feeder in the ring shape of the upper side; And
And a discharge pipe extending from the lower side of the support body and installed toward the belt conveyor, the discharge pipe being a discharge passage of the transported material moving along the support body.
3. The method of claim 2,
The support portion, the feeder for the rotary feeder of the continuous unloader characterized in that it further comprises a fixing member extending from the guide member of the rotary feeder to support the support body.
The method of claim 1,
The moving panel is formed in the same shape as the cross-sectional shape of the support portion, the feeder for a rotary feeder of the continuous unloader, characterized in that a plurality is installed along the circumference of the rotating plate.
The method of claim 4, wherein
And a buffer member made of an elastic material to reduce impact by being installed around the moving panel in contact with the support part.

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